Ten of our favourite early years problem-solving activities

Ten of our favourite early years problem-solving activities - Featured Image

A lot of the time when we hear the term ‘problem-solving’, our brain jumps back to the tricky maths teasers from our school days, and we immediately recoil a little. However, problem-solving is much more than number conundrums.   

Problem-solving is a key part of early years development and can support learning across many of the My First Five Years streams. The skill of problem-solving starts developing very early in a child's life and stems from the knowledge of the world that they are constantly building.[1]. For instance, your baby may cry when hungry as they know that crying gets the attention of an adult who can feed them.   

Problem-solving is a part of everyday life for children, from being a baby through to their future adulthood. When children learn how to solve problems, it can support them in building resilience, self-confidence and self-esteem. Taking part in problem-solving activities with others can also help children develop social skills, communication and relationships.[2]   

Psychologist Jean Piaget’s theory of cognitive development also focuses on the importance of problem-solving for early childhood development. In each developmental stage of his theory, the psychologist emphasised the importance of play-based learning for young children when it comes to problem-solving, and in turn building skills across the spectrum.[3]    

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Supporting problem-solving  

When thinking about problem-solving activities for your child, it can be difficult to know where to begin.   

To keep children engaged, enabling them to take the lead and follow their interests, is key. Play-based, hands-on learning makes acquiring new skills more interesting and memorable for young children.[4]    

Many activities can support children when developing their problem-solving abilities – the possibilities are wide open. When considering which problem-solving activities are the most effective, it is also important to consider how they can be adapted to multiple interests, abilities and how accessible they are when it comes to using resources and materials.   

To help you out, here are ten of My First Five Years’ favourite problem-solving activities that you can try with your child.   

1) Den-building

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Den-building is brilliant for problem-solving as it requires creative and critical-thinking, foresight, and planning. It is also a wonderful way to promote sustained shared thinking with your child. Sustained shared thinking is a way of working together that encourages individuals to evaluate the problem that they are working on and is focused on collaboration, using experiences and prior knowledge.[5]  

When building a den with your child, encourage your child to take the lead. You could provide materials such as boxes and blankets, or you could even ask your child to decide what materials you need before starting, encouraging them to plan out their work. Den-building can also be done both indoors and outdoors and with children from a young age. You may find that people have already started creating these in your local woodland that you can add to, adapt, or just enjoy!  

2) Cooking and baking

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Cooking and baking are not only fun activities, but they also focus on mathematical problem-solving. To bring problem-solving into a cooking and baking activity, you can ask your child to count out simple measurements, for instance, cups of flour or sugar. Activities like cooking or baking are great for children to be able to take ownership of what is happening; encourage them to choose what you will make and allow them to do all the elements themselves.   

What’s great about cooking is it really doesn't matter how it turns out! Problems can arise often in cooking or baking, for example, the mixture may turn out too dry, you may be an ingredient short, or your cakes might not rise how you expected them to. If this is the case, talk to your child about what might have gone wrong and how you can rectify it next time! Then when they come to do it again, they can use their prior knowledge to help them.   

3) Playing with patterns

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Patterns are a great activity for mathematical problem-solving. You can create patterns of any objects that you can find! For example, with pieces of fruit, pebbles from the garden, building blocks or even snacks! You could encourage your child to continue patterns, fill in the missing pieces or even create their own for you to solve problems with as they grow more confident. 

4) Sorting and categorising

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Sorting and categorising objects is an activity that supports children in mathematical problem - solving and can be easily adapted to individual children’s abilities . You could encourage your child to sort by shape, size, colour, or better yet , their interests . For example, if they are a dinosaur enthusiast, they could classify them by wh ich is their favourite or least favourite , or order them by the size of their feet. They may even find enjoyment in helping you with daily sorting such as recycling or washing!  

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Puzzles are a fun resource that can be used with children from a very young age. There are a wide variety of puzzles for children to access , such as chunky wooden puzzles or traditional shape sorters. When playing with puzzles, children will have to use their prior knowledge and experience of shape, space and measure whil e also experimenting with different angles and placements. They will use trial and error to find the best way to complete the puzzle and then will use this knowledge in future attempts.  

6) Ice rescue

As well as being a great problem-solving activity, ice rescue enables children to explore seasonal changes, temperatures and develop their fine and gross motor skills using tools. To play ice rescue, freeze toys inside ice overnight. This could be in cake moulds or small bowls. Use toys that will motivate your child, for instance, their favourite small figurines.   

Once frozen, place your blocks of ice in a big bowl or tray, and encourage your child to think about how they can get the items out. You could provide tools, or even get your child to find tools themselves.  

7) Obstacle courses

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Obstacle courses are versatile and can be made with a wide variety of resources. When setting up an obstacle course for your child, try to include sections where your child will have to stop and think about how they will have to adapt their body to move through it , for example, something that they must climb over or under, or a section where they have to move differently. You could even include them in trying to create the obstacle course and allow them to make it the most challenging they can.  

8) Filling, emptying and investigation

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Many children enjoy filling and emptying during play. Investigating this way helps children to get a sense of size, capacity and explore predicting and estimation. For instance, if your child likes playing with sand, you could ask them to guess how many scoops they will need to fill a container, or if they like water play you could challenge them to find a way to move the water between two containers as quickly as possible , or from one tray to another.  

9) Story problems

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Stories are an effective way of introducing problem-solving and they can be a highly engaging way to promote creative and critical-thinking. You could use familiar or traditional stories to help scaffold play opportunities for your child. For example, you could try building a house for the three little pigs that cannot be knocked over. You could test out different methods using materials that you can find around your home.   

If you are feeling creative, you could also make up a little story using your child’s favourite toys. An example of this could be figuring out how to share food between their favourite teddies during a picnic and making sure that everyone gets enough.   

10) Playing with loose parts or open-ended resources

Natural materials such as leaves, conkers, sticks, acorns, and pinecones are all brilliant open-ended play opportunities (if supervised). You can also use household objects like bottle caps, curtain rings, tubes, tins, boxes, buttons etcetera in this sort of play. All it requires is a tray of different objects that you've collected and time to explore them. Your child will have to think creatively about how to utilise the objects and in doing so will be challenging their cognitive capacity by problem-solving to achieve the desired outcomes.   

References 

[1]  Rachel Keen. (2011). The Development of Problem Solving in Young Children: A Critical Cognitive Skill. Available: https://www.annualreviews.org/doi/full/10.1146/annurev.psych.031809.130730#_i22 .  

[2] Sheila Ebbutt. (2009). EYFS best practice - All about ... problem-solving . Available: https://www.nurseryworld.co.uk/features/article/eyfs-best-practice-all-about-problem-solving .  

[3] Piaget, J. (1983). Piaget's Theory. In P. Mussen (ed). Handbook of Child Psychology. 4th edition. Vol. 1. New York: Wiley.  

[4] Unicef. (2018). Learning Through Play. Available: https://www.unicef.org/sites/default/files/2018-12/UNICEF-Lego-Foundation-Learning-through-Play.pd .  

[5] Kathy Sylva, Edward Melhuish, Pam Sammons, Iram Siraj-Blatchford and Brenda Taggar. (2004). The Effective Provision of Pre-School Education (EPPE) Project: Findings from Pre-school to end of Key Stage1. Available: https://dera.ioe.ac.uk/8543/7/SSU-SF-2004-01.pdf .  

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Maths problem-solving – Activities for Early Years settings

  • Written By: Judith Dancer
  • Subject: Maths

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Maths problem-solving – Activities for Early Years settings

Critical thinking doesn’t have to be a daunting prospect. There are simple, effective and exciting ways to encourage children’s maths problem-solving skills, says Judith Dancer…

Maths is a subject many adults lack confidence in. Having struggled with it at school they often avoid it, wherever possible, when grown up.

But if maths seems scary for some people, then maths problem-solving can cause even more anxiety. There is no ‘safety net’ of knowing the ‘correct answer’ beforehand. This is because maths problem-solving lends itself to investigation and exploration with lots of possible tangents.

Understandably this is often the area of maths where many practitioners feel least confident. However, young children, who are not restrained by right answers, feel the most enthused and animated.

The non-statutory  Development Matters Guidance , as part of ‘creating and thinking critically’ in the Characteristics of Effective Learning, identifies that practitioners need to observe how a child is learning, noting how a child is:

  • thinking of ideas;
  • finding ways to solve problems;
  • finding new ways to do things;
  • making links and noticing patterns in their experience;
  • making predictions;
  • testing their ideas;
  • developing ideas of grouping, sequences, cause and effect;
  • planning, making decisions about how to approach a task, solve a problem and reach a goal;
  • checking how well their activities are going;
  • changing strategy as needed;
  • reviewing how well the approach worked.

All of these elements are, at one time or another, part of the problem-identifying and solving process – although not at the same time and in the same problem.

Role of the adult

Maths problem-solving for young children involves them understanding and using two kinds of maths:

  • Maths knowledge – learning and applying an aspect of maths such as counting, calculating or measuring.
  • Maths thinking skills – reasoning, predicting, talking the problem through, making connections, generalising, identifying patterns and finding solutions.

The best maths problems for children are the ones that they identify themselves. They will be enthused, fascinated and more engaged in these ‘real’, meaningful problems.

Children need opportunities to problem-solve together. As they play, they will often find their own mathematical problems.

One of the key roles of practitioners is to provide time, space and support for children. We need to develop situations and provide opportunities in which children can refine their maths problem-solving skills and apply their mathematical knowledge.

Supporting maths problem-solving

You can effectively support children’s developing maths problem-solving strategies through:

  • Modelling maths talk and discussion – language is part of maths learning because talking problems through is vital. Children need to hear specific mathematical vocabulary in context. You can promote discussion through the use of comments, enabling statements and open-ended questions.
  • Providing hands-on maths problem-solving activities across all areas of the setting. Children learn maths through all their experiences and need frequent opportunities to take part in creative and engaging experiences. Maths doesn’t just happen in the maths learning zone!
  • Identifying potential maths learning indoors and outdoors. Provide rich and diverse open-ended resources that children can use in a number of different ways to support their own learning. It is important to include natural and everyday objects and items that have captured children’s imaginations, including popular culture.

Maths problem-solving possibilities

Spell it out.

This experience gives children lots of opportunities to explore calculating, mark making, categorising and decisions about how to approach a task.

What you need to provide:

  • Assorted containers filled with natural materials. This includes leaves, pebbles, gravel, conkers, twigs, shells, fir cones, mud and sand. Include some ‘treasure’ – sequins, gold nuggets, jewels and glitter.
  • Bottles and jugs of water, large mixing bowls, cups, a ‘cauldron’, small bottles, spoons and ladles.
  • Cloaks and wizard hats.
  • Laminated ‘spells’ – e.g. “To make a disappearing spell, mix 2 smooth pebbles, 2 gold nuggets, 4 fir cones, a pinch of sparkle dust, 3 cups of water”.
  • Writing frameworks for children’s own spell recipes and a shiny ‘Spell Book’ to stick these in.
  • Temporary mark-making opportunities such as chalk on slate.

The important thing with open-ended maths problem-solving experiences like this is to observe, wait and listen. Then, if appropriate, join in as a co-player with children, following their play themes.

So if children are mixing potions, note how children sort or categorise the objects. What strategies do they use to solve problems? What happens if they want eight pebbles and they run out? Observe what they do next.

When supporting children’s maths problem-solving, you need to develop a wide range of strategies and ‘dip into’ these appropriately. Rather than asking questions, it is often more effective to make comments about what you can see. For example, say, “Wow, it looks as though there is too much potion for that bottle”.

Acting as a co-player offers lots of opportunities to model mathematical behaviours. This might include reading recipes for potions and spells out loud, focusing on the numbers – one feather, three shells…

Going, going, gone

We all know that children will engage more fully when involved in experiences that fascinate them. If a particular group has a real passion for cars and trucks , consider introducing maths problem-solving opportunities that extend this interest.

This activity offers opportunities for classifying, sorting, counting, adding and subtracting, among many other things.

  • Some unfamiliar trucks and cars and some old favourites. Ensure these include metal, plastic and wooden vehicles that can be sorted in different ways.
  • Masking tape and scissors.
  • Sticky labels and markers.

Mark out some parking lots on a smooth floor, or huge piece of paper using masking tape. Lining paper is great for this. Line the vehicles up around the edge of the floor area.

Encourage one child to select two vehicles that have something the same about them. Ask the child, “What is the same about them?”.

When the children have agreed on what is the same – e.g. size, materials, colour, lorries or racing cars – the child selects a ‘parking lot’ to put the vehicles in. So this first parking lot could be for ‘red vehicles’.

Another child chooses two more vehicles that have something the same. Do they belong in the same ‘parking lot’, or a different parking lot? E.g. these vehicles could both be racing cars.

What happens when a specific vehicle could belong in both lots? E.g. it could belong in the set of red vehicles and also belongs in the set of racing cars.

Support the children as they discuss the vehicle. Make new ‘parking lots’ with masking tape and create labels for the groups, if you choose.

Observe children’s strategies

It’s really important to observe the strategies the children use. Where appropriate, ask the children to explain what they are doing and why.

If necessary, introduce and model the use of the vocabulary ‘the same as’ and ‘different from’. Follow children’s discussions and interests. If they start talking about registration plates, consider making car number plates for all the wheeled toys outdoors.

Do the children know the format of registration plates? Can you take photos of cars you can see in the local environment?

Camping out

Constructing camps and dens outdoors is a good way to give children the opportunity to be involved in lots of maths problem-solving experiences and construction skills learning. This experience offers opportunities for using the language of position, shape and space, and finding solutions to practical problems.

  • Materials to construct a tent or den such as sheets, curtains, poles, clips and string.
  • Rucksacks, water bottles, compasses and maps.
  • Oven shelf and bricks to build a campfire or barbecue.
  • Buckets and bowls and water for washing up.

Encourage the children to explore the resources and decide which materials they need to build the camp. Suggest they source extra resources as they are needed.

Talk with the children about the best place to make a den or erect a tent and barbecue. During the discussion, model the use of positional words and phrases.

Follow children’s play themes. This could include going on a scavenger hunt collecting stones, twigs and leaves and going back to the campsite to sort them out.

Encourage children to try different solutions to the practical problems they identify. Use a running commentary on what is happening without providing the solution to the problem.

Look for opportunities to develop children’s mathematical reasoning skills by making comments such as, “I wonder why Rafit chose that box to go on the top of his den.”

If the children are familiar with traditional tales, you could extend this activity by laying a crumb trail round the outdoor area for children to follow. Make sure that there is something exciting at the end of the trail. It could be a large dinosaur sitting in a puddle, or a bear in a ‘cave’.

Children rarely have opportunities to investigate objects that are really heavy. Sometimes they have two objects and are asked the question, “Which one is heavy?” when both objects are actually light.

This experience gives children the chance to explore really heavy things and measures (weight). They also need to cooperate and find new ways to do things.

  • A ‘building site’ in the outdoor area. Include hard hats, builders’ buckets, small buckets, shovels, spades, water, sand, pebbles, gravel, guttering, building blocks, huge cardboard boxes and fabric (this could be on a tarpaulin).
  • Some distance away, builders’ buckets filled with damp sand and large gravel.
  • Bucket balances and bathroom scales.

With an open-ended activity such as this, it is even more important to observe, wait and listen as the children explore the building site and the buckets full of sand and gravel.

Listen to the discussions the children have about moving the sand and the gravel to the building site. What language do they use?

Note the strategies they use when they can’t lift the large buckets. Who empties some of the sand into smaller buckets? Who works together collaboratively to move the full bucket? Does anyone introduce another strategy, for example, finding a wheelbarrow or pull-along truck?

Where and when appropriate, join in the children’s play as a co-player. You could act in role as a customer or new builder. Ask, “How can I get all this sand into my car?”. “How much sand and gravel do we need to make the cement for the foundations?”.

Extend children’s learning by modelling the language of weight:

  • heavy/heavier than/heaviest
  • light/lighter than/lightest
  • about the same weight as/as heavy as
  • balance/weigh

Judith Dancer is an author, consultant and trainer specialising in communication and language and mathematics. She is co-author, with Carole Skinner, of  Foundations of Mathematics – An active approach to number, shape and measures in the Early Years .

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Empowered Parents

10 Simple Activities to Teach Your Preschooler Problem Solving

By: Author Tanja McIlroy

Posted on Last updated: 14 November 2023

Categories Cognitive Development

problem solving skills early years

During the first years of a child’s life, an important set of cognitive skills known as problem-solving abilities are developed. These skills are used throughout childhood and into adulthood.

Find out what problem solving is, why it’s important and how you can develop these skills with 10 problem-solving games and activities.

What is Problem Solving in Early Childhood?

So, what exactly is problem solving? Quite simply, it refers to the process of finding a solution to a problem .

A person uses their own knowledge and experience, as well as the information at hand to try and reach a solution. Problem solving is therefore about the thought processes involved in finding a solution.

This could be as complex as an adult working out how to get out of a financial crisis or as simple as a child working out how two blocks fit together.

Problem Solving Skills for Kids

Problem-solving skills refer to the specific thinking skills a person uses when faced with a challenge. Some problems require the use of many skills, while others are simple and may only require one or two skills.

These are some examples of problem-solving skills for preschoolers , as listed by kent.ac.uk .

  • Lateral thinking
  • Analytical thinking
  • Decision-making skills
  • Logical reasoning
  • Persistence
  • Communication skills
  • Negotiation skills

The Importance of Developing Problem-Solving Skills in Early Childhood

Problem solving is a skill that would be difficult to suddenly develop as an adult. While you can still improve a skill at any age, the majority of learning occurs during the early years.

Boy thinking about a problem

Preschool is the best time for a child to learn to problem solve in a fun way. The benefits of learning early will last a lifetime and the beauty of learning anything at a young age is that it is effortless .

It is like learning to play an instrument or picking up a new language – it’s just much easier and more natural at an early age.

Of all the many things preschoolers need to learn , what makes problem solving so important?

There aren’t many situations in life, at work or at school that don’t require some level of problem resolution.

Child’s play itself is filled with opportunity upon opportunity to solve all kinds of tricky situations and come up with solutions to challenges.

Problem Solving in Preschool

During the foundational years, children are constantly solving problems as they play .

Here are just a few examples of problem solving in early childhood :

  • Resolving a fight over the same toy
  • Reaching a ball that’s stuck in the tree
  • Forming a circle while holding hands
  • Making a bridge to connect two block towers
  • Tying or untying a shoe
  • Making up rules for a new game
  • Trying to get the consistency of a mud cake right so it stops falling over

The more creative play opportunities and challenges children are given, the more they get to exercise their problem-solving muscles.

During free play , there are non-stop experiences for this, and parents and teachers can also encourage specific problem-solving skills through guided activities .

Problem Solving for Older Children

During the grades, children experience problems in many forms, some of which may be related to their academic, social and emotional well-being at school. Problems may come in the form of dealing with life issues, such as:

  • Problems with friendships
  • Struggling to understand something during a lesson
  • Learning to balance the demands of sport and homework
  • Finding the best way to study for a test
  • Asking a teacher for help when needed

Problems will also form a large part of academic life as teachers will be actively developing this skill through various activities, for example:

  • Solving a riddle or understanding a work of literature
  • Working on projects with a friend
  • Finding solutions during science experiments
  • Solving mathematical problems
  • Solving hypothetical problems during lessons
  • Answering questions and completing exam papers

Children who have had practice during preschool will be a lot more capable when facing these challenges.

Solving Problems in Mathematics

Mathematics needs to be mentioned separately as although it is part of schooling, it is such a huge part and it depends heavily on a child’s ability to solve problems.

The entire subject of mathematics is based on solving problems. Whether you are adding 2 and 3, working out how many eggs will fit into each basket, or solving an algebraic expression, there is a problem in every question.

Mathematics is just a series of problems that need to be solved.

What we refer to as problem solving in Maths is usually answering word problems .

The reason many children find these so difficult to answer is that the question is presented as a problem through a story, rather than just numbers with symbols telling you what operation to use (addition, division, etc.)

This means a child is forced to think carefully, understand the problem and determine the best way to solve it.

These problems can involve various units (e.g. mass, capacity or currency) as well as fractions, decimals, equations and angles, to name a few. Problems tend to become more and more complex over the years.

My experience in the classroom has shown that many, many children struggle with solving word problems, from the early grades right into the senior years.

They struggle to analyze the question, understand it, determine what information they’ve been given, and what exactly they are required to solve.

The good news is that exposing a child to regular problem-solving activities and games in preschool can greatly help him to solve word problems later on in school.

If you need one good reason to do these kinds of activities, let it be for a smoother experience in mathematics – a subject so many children unnecessarily fear.

Problem Solving in the Workplace

Lady at work doing problem solving

Adults in the workplace seldom thrive without problem-solving skills. They are required to regularly solve problems .

As adults, employees are expected to independently deal with the frequent challenges, setbacks and problems that are a big part of every working environment.

Those who can face and solve their own problems will go further and cope better than those who seek constant help from others or cannot show initiative.

Some  career websites even refer to problem solving as a universal job skill. They also mention that many employees are not good at it. 

Again, although it may seem far removed, learning this skill at a young age will help a child cope right into adulthood and in the working world.

Pinterest image - 10 simple activities to teach problem solving.

How to Teach Children Problem-Solving Skills

If early childhood is the best time to grow these skills in your young children, then how does one go about teaching them to toddlers, preschoolers and kindergarteners?

Mom and child constructing

Problem solving can be taught in such a way that you expose your child to various opportunities where they will be faced with challenges.

You would not necessarily sit your 3-year-old down and tell or “teach” him all about fixing problems. Instead, you want to create opportunities for your child to grow this skill .

Using the brain to think and find solutions is a bit like working a muscle over time. Eventually, your muscle gets stronger and can handle more “ weight. ” Your child will learn to problem solve in two ways:

  • Incidentally – through free play
  • Through guided opportunities provided by a parent or teacher

If you make a point of encouraging thinking through games and activities, your child will develop stronger skills than if you let it all happen incidentally.

Problem-Solving Strategies and Steps

If we take a look at the steps involved in solving a problem, we can see that there are many layers involved and different types of skills. Here are the problem-solving steps according to the University of Ken. 

Step 1: Identify the problem

Step 2: Define the problem

Step 3: Examine the options

Step 4: Act on a plan

Step 5: Look at the consequences

Therefore, activities at a preschool level need not present complicated high-level problems.

  • A simple activity such as identifying differences in a picture can work on the first skill needed – identifying a problem.
  • Playing with construction toys can develop a child’s ability to try various solutions and examine the options when faced with a problem such as trying to find the best way to build something.
  • Playing Tic-Tac-Toe would make a child predict the consequences of placing their mark in a particular square.

The most basic of activities can work on all these skills and make children competent solution finders.

How to Teach Problem Solving with Questions

The language you use around your child and your questioning technique will also greatly affect their understanding of a problem or challenge as merely something waiting for a solution to be found .

While your child is playing or when she comes to you with a problem, ask open-ended questions that will guide her in finding a potential answer independently. Use the steps listed above to formulate your questions.

Here are some examples of questions:

  • What do you think made the tower of blocks fall down?
  • If we build it again, how can we change the structure so that it won’t fall down next time?
  • Is there a better way we can do it? If you think of a different way, we can both try it and see which works better.
  • Did that work? The tower fell again so let’s try another solution.

Resist the temptation to fix every one of your child’s problems, including conflict with friends or siblings. These are important opportunities for children to learn how to resolve things by negotiating, thinking and reasoning.

With time, your child will get used to seeing a problem, understanding it, weighing up the options, taking action and evaluating the consequences.

Problems will be seen as challenges to be faced logically and not “problems.”

This post contains affiliate links for educational products that I personally recommend. If you purchase through one of them, I earn a commission at no extra cost to you. Read the terms and conditions for more details.

10 Problem-Solving Activities for Preschoolers

Here are 10 simple, easy games and problem solving activities for kids at home or at school. Many of them are the kinds of activities children should have daily exposure to.

Puzzles are one of the best thinking activities out there. Each puzzle is basically one big set of muddled-up things to be sorted out and put back together again. Find out why puzzles are important for development .

Children should have regular exposure to puzzles. They are great for developing thinking skills.

problem solving skills early years

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2. Memory games

Memory games will develop your child’s memory and attention to detail.

Get your own memory game cards by downloading the FREE set of printables at the end of the post.

Use pairs of matching pictures and turn them all face down, shuffled, on a table. Take turns choosing any two cards and turning them face up on the table. If you turn over a matching pair you keep the cards and if the pair doesn’t match, turn the cards back over until it is your turn to try again.

Encourage your child to concentrate and pay attention to where the pictures are and try to find a matching pair on each turn. 

3. Building with Construction Toys

Construction toys such as engineering blocks, a proper set of wooden blocks or Legos (shown below) should be a daily staple in your home.

Everything your child builds is a challenge because it requires thinking about what to build and how to put the pieces together to get a design that works and is functional.

Leave your child to construct freely and occasionally set a challenge and ask him to build a specific structure, with conditions. For example:

  • Make two towers with a bridge joining them together
  • Build a creature that stands on its own and has 3 arms.

Then watch your child wracking his brain until he finds a way to make his structure work.

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4.  Activity Books

These activity books are really fun and develop a child’s ability to identify problems and search for information.

problem solving skills early years

  • Pomaska, Anna (Author)
  • English (Publication Language)

problem solving skills early years

  • Handford, Martin (Author)

Help! My Dinosaurs are Lost in the City!: A Fun Spotting Book for 2-4 Year Olds (Help!...

  • Books, Webber (Author)

5. Following Patterns

This simple activity can be played with a set of coloured blocks, shapes or counters.

Simply make a pattern with the blocks and ask your child to continue it. Vary the pattern by changing the colours, shapes or sizes.

This activity will train your child to analyse the given information, make sense of it, recognise the pattern and re-create it.

6. Story Time Questions

Get into the habit of asking questions during your daily story time that develop higher-order thinking skills . Instead of just reading and your child passively listening, ask questions throughout, concentrating on solving problems.

Here are some examples:

  • Why do you think the bear did that?
  • Do you think his friend will be happy? Why?
  • What would you do if you were the monkey?
  • How do you think Peter can make things better with his friend?
  • If the crocodile had decided not to eat the rabbit, how could the story have ended?

7. Board Games

Board games are an excellent way to develop problem-solving skills.

Start off with simple games like Ludo and Snakes and Ladders to teach the skill of following rules and moving in a logical sequence.

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problem solving skills early years

Card games like Go Fish are also great for teaching young children to think ahead and solve problems.

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8.  Tic-Tac-Toe

This is a perfect game to teach decision-making skills , thinking before acting and weighing up the possible consequences.

Tic-tac-toe game

Use a Tic Tac Toe Board or d raw a simple table like the one above on paper or a chalkboard.

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Take turns to add a nought or a cross to the table and see who can make a row of three first.

Your child will probably catch on in no time and start thinking carefully before placing their symbol. This game can also be played with coloured counters or different objects.

9. Classifying and Grouping Activities

This activity can be done with a tin of buttons or beads or even by unpacking the dishwasher. The idea is to teach the skill of classifying and categorizing information by learning with physical objects. Here are some other ideas for categorizing:

  • Separate the washing – mom’s clothes, dad’s clothes, etc; or socks, tops, shorts, etc.
  • Empty out the cutlery drawer for cleaning, mix all the utensils up and then sort into knives, tablespoons, teaspoons, etc.
  • Classify and sort out the toys in your child’s bedroom together – all books, construction toys, soft toys, etc.
  • Play category games .

Here are more button activities for kids .

10. Building a Maze

This activity is lots of fun and suitable for any age. It is also going to be way more fun than doing a maze in an activity book, especially for younger children.

Draw a big maze on the paving with sidewalk chalk . Make passages, including one or two that end in a dead-end. Teach your child to find her way out .

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As your child gets better at figuring out a route and finding the way out, make the maze more complex and add more dead-end passages.

Get FREE access to Printable Puzzles, Stories, Activity Packs and more!

Sign up and you’ll receive a downloadable set of printable puzzles, games and short stories , as well as the Learning Through Play Activity Pack which includes an entire year of activities for 3 to 6-year-olds. Access is free forever.

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Friday 3rd of June 2022

hi maam , This Is Uma from India,Can i get this in pdf format or a book. Thank You

Tanja Mcilroy

Monday 6th of June 2022

Hi Uma, thanks for your message. These articles are not available in PDF, but you are welcome to copy and paste them from the website, as long as you add the reference: https://empoweredparents.co/problem-solving-activities-preschoolers/ Thanks for reading!

Wednesday 20th of May 2020

Very very useful content. Good work. Thank you.

Friday 22nd of May 2020

Thanks Ann.

Tuesday 19th of May 2020

Would like to download the free activity pack please.

Hi Kelly, Please download the activity pack on this page: www.empoweredparents.co

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Approaches to Learning: Problem Solving

problem solving skills early years

Birth to 9 months

7 months to 18 months, 16 months to 24 months, 21 months to 36 months.

Children attempt a variety of strategies to accomplish tasks, overcome obstacles, and find solutions to tasks, questions, and challenges.

Children build the foundation for problem-solving skills through nurturing relationships, active exploration, and social interactions. In infancy, children learn that their actions and behaviors have an effect on others. For example, children cry to signal hunger to their caregivers; in turn, their caregivers feed them. Caregivers’ consistent responses to children’s communication attempts teach children the earliest forms of problem solving. Children learn that they have the ability to solve a problem by completing certain actions. Children build this knowledge and translate it into how they interact and problem-solve in future situations.

Children discover that their actions and behaviors also have an impact on objects. They learn that certain actions produce certain results. For example, children may bang a toy over and over as they notice the sound that it makes. This behavior is intentional and purposeful; children learn that they have the ability to make something happen. As they get older, children will experiment with different ways to solve problems, such as moving puzzle pieces in different ways to place them correctly. They will use trial and error to find solutions to the tasks they are working on, and use communication skills to ask or gesture for help from caregivers.

By 36 months, children are able to decrease the amount of trial and error they use when solving problems. Their cognitive skills are maturing and they are able to use logic and reasoning when working through challenges. Increased attention allows children to focus for longer periods of time when working through challenges. Children still depend on their caregivers for help, but are likely to attempt problem solving on their own before asking someone for help.

Children are building the foundation for problem solving through active exploration and social interaction.

Indicators for children include:

  • Focuses on getting a caregiver’s attention through the use of sounds, cries, gestures, and facial expressions
  • Enjoys repeating actions, e.g., continues to drop toy from highchair after it is picked up by a caregiver or sibling
  • Communicates the need for assistance through verbal and/or nonverbal cues, e.g., pointing, reaching, vocalizing

Strategies for interaction

  • Respond thoughtfully and promptly to the child’s attempts for attention
  • Provide interesting and age-appropriate toys and objects for exploration
  • Engage and interact with the child frequently during the day

Children begin to discover that certain actions and behaviors can be solutions to challenges and obstacles they encounter. Children also recognize how to engage their caregiver(s) to assist in managing these challenges.

  • Repeats actions over and over again to figure out how an object works
  • Begins to recognize that certain actions will draw out certain responses, e.g., laughing and smiling will often result in an adult responding in the same manner
  • Attempts a variety of physical strategies to reach simple goals, e.g., pulls the string of a toy train to move it closer or crawls to get a ball that has rolled away
  • Demonstrate how to try things in different ways and encourage the child to do the same, e.g., using a plastic bucket as a drum
  • Gently guide the child in discovering and exploring, while allowing him or her enough independence to try new things
  • Respond thoughtfully and promptly to the child’s communication attempts

Children have an enhanced capacity to solve challenges they encounter through the use of objects and imitation. Children may take on a more autonomous role during this stage, yet, reach out to caregiver(s) in most instances.

  • Imitates a caregiver’s behavior to accomplish a task, e.g., attempts to turn a doorknob
  • Increases ability to recognize and solve problems through active exploration, play, and trial and error, e.g., tries inserting a shape at different angles to make it fit in a sorter
  • Uses objects in the environment to solve problems, e.g., uses a pail to move numerous books to the other side of the room
  • Uses communication to solve problems, e.g., runs out of glue during an art project and gestures to a caregiver for more
  • Validate and praise the child’s attempts to find solutions to challenges
  • Narrate while assisting the child in figuring out a solution, e.g., “Let’s try to turn the puzzle piece this way”
  • Provide the child with opportunities to solve problems with and without your help; minimize the possibility for the child to become frustrated
  • Respond to the child’s communication efforts

Children begin to discriminate which solutions work, with fewer trials. Children increasingly become more autonomous and will attempt to first overcome obstacles on their own or with limited support from caregiver(s).

  • Asks for help from a caregiver when needed
  • Begins to solve problems with less trial and error
  • Refuses assistance, e.g., calls for help but then pushes a hand away
  • Shows pride when accomplishing a task
  • Uses increasingly refined skills while solving problems, e.g., uses own napkin to clean up a spill without asking an adult for help
  • Follow the child’s lead and pay attention to his or her cues when assisting in a task
  • Share in the child’s joy and accomplishments
  • Model and narrate problem-solving skills through play
  • Provide the child with blocks of uninterrupted time to work on activities
  • Be available for the child and recognize when he or she needs guidance

Real World Story

Sebastian, who is 25 months old, is engaged in a fine-motor activity provided by his caregiver. He is holding large, plastic tweezers and is attempting to use them to pick up big, fuzzy balls off a plastic plate and move them into a plastic cup. He is holding the plastic tweezers in one hand, and holds the plate steady on the table. He repeatedly tries to use one hand, but cannot pinch the tweezers tightly enough to pick up one of the balls. Sebastian pauses, looks around, and picks up the balls with his thumb and forefinger.

Holding the plastic tweezers in one hand and the ball in the other, Sebastian places the ball in the tweezers and then pinches it closed. He moves it over to the plastic cup and drops it inside. He then grabs another fuzzy ball and places it in the tweezers. Again, he pinches it tightly and transfers it to the cup. Sebastian engages in the same method until all the fuzzy balls on his plate are now inside his cup. Once he is done, he empties out the cup onto the plate and starts all over. After successfully completing the process again, he holds out his full cup toward his caregiver, Maria. She sees him, smiles, and gives two thumbs up. Sebastian grabs his cup and walks over to her. He hands Maria the cup and walks away from the table.

Discover how this Real World Story is related to:

  • Self-Regulation: Foundation of Development Attention Regulation
  • Developmental Domain 1: Social & Emotional Development Self-Concept
  • Developmental Domain 2: Physical Development & Health Fine Motor
  • Developmental Domain 2: Physical Development & Health Perceptual
  • Developmental Domain 4: Cognitive Development Logic & Reasoning

THIS EXAMPLE HIGHLIGHTS how children use physical trial and error to solve problems. Sebastian is not successful in his initial attempts to pick up the small objects with his tweezers. However, he pauses to think about possible ways to work on this problem, and then changes his process. Instead of pinching the tweezers to grab the ball, he places the ball in between the tweezers and then pinches it closed. This is easier for him, as he is still developing the fine motor skills necessary to be able to complete this task. Once he realizes he is successful in accomplishing his goal, he engages in this task until he has finished placing every ball on his plate into the cup. He then repeats the activity all over again. Sebastian’s ability to successfully problem solve builds his self-confidence. Maria’s positive acknowledgment of his accomplishment further supports his social and emotional development. A positive self-concept and increasing self-confidence is very important for Sebastian’s future learning and overall healthy development.

Discover how Problem Solving is related to:

  • Self-Regulation: Foundation of Development Emotional Regulation
  • Developmental Domain 1: Social & Emotional Development Relationship with Adults
  • Developmental Domain 4: Cognitive Development Memory

Related Resources

  • Teaching & Learning
  • Early Years

Problem-solving in early maths: 3 simple teaching tips

Problem-solving in early maths: 3 simple teaching tips

E d has made an enclosure for dinosaurs using four wooden blocks. He wants to make sure the dinosaurs can’t escape.

“Interesting, I can see the dinosaurs are all locked inside the enclosure,” says Ed’s teacher, “but the tyrannosaurus rex is very tall. I think it would be able to climb out? Is there something you could do to stop him escaping?”

Ed fetches four more blocks and stacks them on top of his enclosure, making it taller.

“Good thinking, Ed,” says the teacher, “but we can still see his head, so it might need to be taller. There are no more long blocks for you to use. I wonder what you could use instead?”

“I think lots of these shorter ones might fit on the top,” says Ed.

  • What would “phonics for maths” look like?
  • Is this the “right” way to teach early maths?
  • How to develop number sense

There are frequent opportunities for mathematical problem-solving throughout a typical day in an early years setting. But how can we ensure that we maximise their impact when they arise?

The Education Endowment Foundation’s Early Years Evidence Store identifies approaches that educators can use to support young children’s early maths learning and development, while providing a summary of the evidence behind each approach.

Created as part of the EEF’s work supporting the Department for Education’s Stronger Practice Hubs, the store has been co-developed by researchers and educators.

The newly published Early Mathematics theme recommends five approaches for supporting children’s maths development:

  • Teaching the association between number and quantity.
  • Promoting fluency with numbers and sequences.
  • Teaching problem-solving skills for maths.
  • Teaching and modelling how to make comparisons and connections.
  • Facilitating mathematical language.

If we look at the third approach, teaching problem-solving skills for maths, this covers how we teach children to apply purposeful thinking, communicate their ideas and use manipulatives to solve problems.

Strategies for teaching early mathematical problem-solving skills

Evidence and experience tell us that explicitly teaching problem-solving skills can be effective when combined with other approaches, especially when matched to children’s level of development.

A multi-pronged approach is particularly important for children from lower-income families or those at greater risk of not meeting expected levels of development. Sequencing learning and breaking tasks down, as well as modelling problem-solving strategies, can also help to improve outcomes.

But what does that look like in practice?

1. Thinking aloud

In the example at the start of this article, Ed’s teacher models her mathematical thinking aloud, encouraging Ed to do the same. Deliberate modelling, meanwhile, provides opportunities for the teacher to suggest additional challenges for Ed’s play in manageable chunks.

2. Modelling using representations to solve a mathematical problem

Educators can encourage children to use representations in different contexts to scaffold understanding.

This could be through using drawings, fingers or objects, such as pinecones or cubes. For example:

Ben is playing with a friend in the mud kitchen. They plan to make “fir cakes” for the teddy bears they have set up on the picnic bench.

Their teacher asks them how many cakes they will make. Ben tells her, “Four, so there is one each.” Andrea encourages Ben to use his fingers to check this, as she points to each teddy.

The teacher counts aloud as Ben lifts each finger, stopping at five.

“I need five cakes then,” Ben says.

“Yes,” the teacher agrees, “you need one more cake, and then there is one for each teddy”.

3. Reminding

Educators can prompt children to remember and apply a previous strategy to solve a mathematical problem. For example:

During welcome time, the teacher asks the class how they can find out how many children are here today, using their self-registration board.

“We can count them,” says Amrita.

“Yes, you are right; we can count the children. Is there a way we can do it that helps us count them correctly?”

The children aren’t sure, so the teacher reminds them: “If we move the photos one by one into the basket as we count, it’ll make sure we only count each photo once.”

Amrita then moves the photos one at a time into the basket as the children count in chorus to work out how many children are at nursery today.

Lauren Grocott is an early years specialist for the Education Endowment Foundation (EEF)

For more examples of how to teach problem-solving, including narration and using mistakes as teaching and learning opportunities, visit the Early Maths theme of the Early Years Evidence Store

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Published 2014 Revised 2018

Mathematical Problem Solving in the Early Years

  • Through our choice of task
  • Through structuring the stages of the problem-solving process
  • Through explicitly and repeatedly providing children with opportunities to develop key problem-solving skills.

problem solving skills early years

  • Describing - these prompts encourage children to talk about their mathematics, which helps organise their thoughts and helps familiarise them with mathematical language
  • Recording - these prompts encourage children to think about how they could keep a record of what they have done, whether to help them explore the mathematics in that moment or to refer back to at another time themselves or to communicate to someone else what they have done
  • Reasoning - these prompts encourage children to connect ideas together, perhaps making logical arguments and to go beyond describing what they have done to explaining why
  • Opening out - these prompts encourage children to explore the context further and possibly more deeply.

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Importance of Problem Solving Skills  and How to Nurture them in your Child

We all face problems on a daily basis. You, me—our kids aren’t even exempted. Across all different age groups, there rarely is a day when we don’t experience them.

Teaching our kids to develop resilience can help as they face these challenges. Practical problem solving skills are just as necessary to teach our kids. The methods needed to resolve problems may require other skills such as creativity, critical thinking, emotional intelligence, teamwork, decision making, etc.

Unlike with math problems, life doesn’t just come with one formula or guidebook that’s applicable to solve every little problem we face. Being adaptable to various situations is important. So is nurturing problem solving skills in your child. 

Here we’ll take a look at the importance of problem solving skills and some ways to nurture them in your child. 

Why do we need problem-solving skills?

One thing that always comes up when we speak of problem-solving skills are the benefits for one’s mental health .

Problems are often complex. This means that problem solving skills aren’t a one-size-fits-all solution to all problems.

Strengthening and nurturing this set of skills helps children cope with challenges as they come. They can face and resolve a wider variety of problems with efficiency and without resulting in a breakdown.

This will help develop your child’s independence, allowing for them to grow into confident, responsible adults. 

Another importance of problem-solving skills is its impact on relationships . Whether they be friendships, family, or business relationships, poor problem solving skills may result in relationships breaking apart.

Being able to get to the bottom of a problem and find solutions together, with all the parties involved, helps keep relationships intact and eliminate conflicts as they arise. Being adept at this skill may even help strengthen and deepen relationships.

problem solving skills early years

What steps can you take to nurture your child’s problem-solving skills?

Nurturing problem-solving skills in your child requires more than just focusing on the big picture and laying out steps to resolve problems. It requires that you teach them to find and focus on a problem’s essential components.

This may challenge your child’s critical thinking and creativity, among other things. 

Critical Thinking

This refers to the ability of breaking down a complex problem and analyzing its component parts.

The ability to do that will make it easier to come up with logical solutions to almost any problem. Being able to sort through and organize that pile of smaller chunks of information helps them face problems with ease. It also prevents your child from feeling overwhelmed when a huge barrier is laid out in front of them. 

Help your child practice critical thinking by asking them questions. Open-ended questions specifically help them think outside the box and analyze the situation.

Teach them to look into possible reasons why something is the way it is. Why is the sky blue? Why are plants green? Encourage them to be curious and ask questions themselves. 

Creative thinking is being able to look at different possible reasons and solutions in the context of problem-solving. It’s coming up with ideas and finding new ways of getting around a problem. Or being open to different ways of looking at an object or scenario.

Creative thinking is best nurtured with activities that involve reflection.

Try getting your child’s viewpoint on topics that may have different answers or reasons for taking place. Get them in the habit of brainstorming ideas, doing story-telling activities, and reading books. All of these help broaden a person’s thinking and flex their creative muscles.

Encourage Independence 

It’s important to retain your role as an observer, supporter, or facilitator. Step back and let your kids try out their own solutions. Watch what happens while ensuring their safety and well-being.

As an observer, you encourage independence by stepping back and watching how your child resolves the problem in their own way. It may take longer than it would if you jumped in, but leaving them to their own devices can do a lot for nurturing their skills at problem solving. 

Support your child by appreciating and acknowledging their efforts. Create a space where they can freely and effectively express their ideas without fear of judgement. Present them with opportunities to play and solve problems on their own. Encourage them to express themselves by brainstorming activities that they might want to do instead of telling them what to do.

These simple steps of overseeing your child can help them become more independent and be resilient enough to tackle problems on their own. 

Here at Early Childhood University , we value the importance of enhancing problem solving skills, creativity and critical thinking. Send your little ones to a school that focuses on a child’s holistic development. Give us a call for more information. 

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Problem-solving and Relationship Skills with Infants and Toddlers

Woman: Places, everyone. Are the lights ready? Three, two, one.

Mike Browne: Ooh-whee! Estoy aqui, estoy listo. I am here. I am ready and let's rock and roll!

Becky Sughrim: I'm ready, too!

All: [Singing] "Teacher Time.” "Teacher Time.” "Teacher Time.” "Teacher Time.” "Teacher Time.” "Teacher Time.”

Mike: Hello, everyone. You know that never gets old. I'm like sitting here jogging along. Welcome, everyone, to our third infant and toddler episode of "Teacher Time" this program year. I'm Mike Browne. My pronouns are he/him. And I'm joined by...

Becky: Becky Sughrim, and my pronouns are she/her.

Mike: And we are from the National Center on Early Childhood Development Teaching and Learning. And as always, we are super excited to be here with you all today. Thank you for joining us. We have been focusing all of our episodes this past season of "Teacher Time" on positive behavior support. So far, we talked about many different things. We talked about the importance of relationships. We talked about how to support emotional literacy. Today is going to be another fun one on problem-solving and friendship skills and building friendship skills with infants and toddlers.

I would love to call to your attention to the Viewer's Guide, where you can find it in the Resource Widget. This season our Viewer's Guide is a Viewer Guide from birth to five. It includes age-specific information for infants, for toddlers, for preschool children. It's packed full of so many different things — resources, helpful quick tips, reminders that you can take right into your learning space. And there's also a note-taking space in which you can use to jot down some notes for today. You can download the guide and use it throughout our time together for taking notes, reflecting, planning, and please, as always share the Viewer Guide with your colleagues.

Becky: During our time together, we're going to be focusing on a number of things. We're going to first talk about some positive behavior support teaching practices. Then we're going to take some time to promote your wellness and our wellness and connect our affective practices to brain development in our new segment this season called "Neuroscience Nook.”

Then we're going to take a look at the "Teacher Time" basics. In "Small Change, Big Impact" and in our "Focus on Equity" segments, we're going to talk about individualized strategies that build a sense of belonging and promote social and emotional skill with all children, including children who have a variety of learning characteristics.

Of course, we will wrap up our time together as we always do with the "BookCASE," where Mike got to meet with our "Teacher Time" librarian, and we connect our topic to books that you can share with children and families.

Mike: As we begin, let's check in using our famous, world famous, "Teacher Time" Tree. Enter to the Q&A, which is that purple widget, what number are you feeling today? What number creature that you're showing up and you want to relate to us. And, of course, you can jot down why you're feeling like that.

I will get us started. I am feeling a little like, I don't know, I like the lighter colors, I like the 11, 12 because yesterday I got a chance to visit a classroom and one of the first children I had when they were infants, they saw me, they ran up to me and they were like, "Mike?” And I was like, "I haven't seen you in two-and-a-half years!” And like, just jumped up and gave me a big hug and now I'm feeling all cuddly and cozy. What about you, Becky?

Becky: That's such a great story. Thanks for sharing, Mike. That makes me feel warm and fuzzy thinking about it. I feel like a number 10. I'm excited for today. I'm ready to be with everyone and just open arms ready to learn and be alongside with you and all of our participants.

Mike: We got some tens, we got some fives in the chat, we've got some ones. Keep them coming. Let us know how you're feeling and we're going to rock and roll to our next slide.

Becky: Thank you. I got a little excited. We are very excited, as you can tell, that we're going to be focusing on positive behavior supports this season. We have focused on this on our last two infant/toddler webinars as well. And you probably already know this, that social-emotional development is one of the domains in Head Start Early Learning Outcomes Framework, or the ELOF. And the practical strategies we're going to be talking about today are going to be focusing on the relationships with other children subdomain of the social-emotional development domain as you can see highlighted here.

We have been working our way through the pyramid. And we've been thinking about the pyramid model, and this is a Positive Behavior Support, or PBS framework that is proactively addressing the social-emotional development and challenging behaviors that young children might experience.

And the framework offers a continuum of evidence-based teaching practices that are organized into four levels of support. The first level is nurturing and responsive relationships. The second level is high-quality supportive environments. Then we have the purple, the third level, social and emotional teaching strategies, and the top of the pyramid, intensive intervention.

And today, we're going to be focusing on that third level of the pyramid, or a second-tier support where we're talking about social and emotional teaching strategies. If you want learn more about the pyramid model, we hope that you will check out the recourses in your viewer's guide from the National Center of Pyramid Model Innovations, or NCPMI in the Resource List section.

Mike: We would love to hear — because I'm already like I need a sip of water — we'd love hear using that purple Q&A widget some of the strategies and practices that you have in place in your center, and your learning environment that really supports problem-solving and relationship skills with infants and toddlers. Once again, type that into the chat using your purple Q&A widget.

Once again, I'm going to start it. I think one practice that I did specifically with infants is whenever we're by the door and it's during pickup time, we will have that child, just look up and we're like, "Oh, is someone's parent here? Or someone's caregiver here?” And they'll go "Dada! Dada!" And I say, "Oh, should we go over to such-and-such, Nico, and say, 'Oh Dada's here?'" "Let's come with me.” You're building that relationship with the child and building relationship between the children.

And something that I like to do with toddlers when they're a little bit older, I love doing like a little scavenger hunt. I'll say, "Oh my goodness! I lost my coffee!” "My adult drink.” Well, maybe not adult drink, some coffee. "Let's go find it!” "Hmm, you're getting warmer. You're getting colder" They've been learning about spatial awareness, difference in temperature, things of that nature.

Becky: And also the collaboration of working together as a team if you're in a group care setting, all trying to find coffee that we need in the morning. Let's see what we have in the Q&A talking about having a welcome song with each child's name.

Mike: We're having some redirect. Redirection is always key.

Becky: Having open-ended questions with toddlers. Totally. And one of the things that I like, which I'm sure is going to also come up in the chat is to engage in that narration when a toy struggle is happening or there's a problem where we're talking about what the toddlers are doing, and what we see. And just letting them know what's happening in real-time.

Mike: That sounds like something we should talk about on Parallel Play.

Becky: Yeah. If you haven't checked out our podcast, we hope that you will. Mike and I also host a Parallel Play podcast. Let's think about positive behavior supports. As we know, the pyramid model is one way we can engage in positive behavior supports. And let's think a little bit deeper about what positive behavior supports are and what they mean. This is really a positive approach to prevent and address challenging behavior or behaviors that adults find challenging.

And the number one thing to remember is that PBS is proactive. That we're proactively thinking about ways in which we can prevent challenging behaviors from occurring. It's positive and proactive. And at the heart of PBS is this recognition that challenging behavior is communication. That challenging behavior is used to communicate a message like, "I want to play with that person or that other toddler.” Or "I want to turn right now.” Or "I want to play in the sensory bin too.” Or something like, "I want that green ball.”

There's all behavior is a form of communication and children are sending us a message. Educators can be their best detectives and together with the family uncover what the child is trying to communicate through their behavior and then teach the child a more effective way to communicate and problem solve with support.

Mike: We’re going to turn it back right to you. I hope your fingers are ready. We're going to be doing this all day. Let's turn the attention back to you. We do our best caregiving and teaching when we feel well ourselves. Really engaging in self-care practices can help educators, admin, everyone build greater social and emotional capacity to work through problem-solving together.

And our ability to support children with problem-solving and relationship skills starts with our ability to really center ourselves by noticing and observing all the little things that are happening within our bodies, with as little judgment as possible and really softening to what is. We can help young children work through challenges with peers, for a more grounded, balance, soft, and objective place by naming what we see happening come. Before we support the children in our care with problem-solving and relationship skills, it's super important that we find ways to regulate our own feelings throughout the day.

Just by taking a minute right now, we're going to do a quick little body scan to know what's happening in our bodies, to really softening to that moment, like I said earlier, slowing down and centering ourselves at any point of the day, but specifically right now since I'm going to ask you all to do it with me. This practice supports our well-being first, enabling us to hold a really non-judgmental space and respond intentionally and responsibly to children cues, behaviors, and communication, as we support them in building healthy relationships with each other. Get your wiggles out.

You might want to start in the seated position, or if you're laying down, maybe you're on a standing desk, I don't know, whatever feels comfortable to you and just start to slowly bring your attention to your body. You can close your eyes. I would love to close my eyes, but the blinding lights are in front of me. I won't do that. Only close your eyes if you're feeling comfortable.

And just start to notice your body wherever you are. As you inhale, and as you exhale have that really sense of relaxation. And you can notice your feet, or your body on the floor. You can notice — for me, I notice the seat underneath me or that if I lean back, the back of the chair against me. That was a lot of words I wanted to say.

Bring your attention now to your stomach area. If it feels tight, right, let us soft it. Imagine you're on a beach somewhere. I know one of our participants says they're going on vacation. Notice your hands, and your arms, and your shoulders. Let them be soft. Let your jaw and your face muscle soften up. And notice your whole body just being present. Then take that one last deep breath.

Now, if you're so inclined to, feel free to share how you are feeling during or feel now after the body scan. What shifts do you notice? Me, oh, I was like, I got a lot of things in my shoulders. I was like, I need to go to a massage place.

Becky: I was thinking the same thing. So much tension I hold in my shoulders and my neck. We're on the same page, Mike.

Mike: There you go.

Becky: As these are coming in let's start to think about problem-solving in relationship skills. Social competencies like self-regulation, empathy, perspective-taking, and problem-solving skills are all really key to foundational healthy social-emotional development. This includes positive interactions and friendships, or relationships between peers. Educators can help children learn these skills that are necessary to develop healthy peer relationships and find ways to work though social conflicts with children and providing support with the child.

The first thing that we can do with infants and toddlers is about modeling problem-solving skills. And if we model problem-solving skills early on, this will build a foundation of problem-solving and relationship skills that children can build on and will be able to access with adult support as they develop and start to use these skills more independently. As children become more independent and more mobile, they tend to run into situations in the natural environment that can lead to frustration or challenging behavior like a toy is out of my reach, or I also want to play in the sensory table and someone is already there.

If we teach children problem-solving skills and they become good problem solvers on their own, and with our support, their self-esteem increases in their ability to solve problems. They're more likely to cope with a certain level of frustration and engage in less challenging behavior. There might be some children in your care who don't readily learn these skills through foundational teaching strategies like modeling or co-regulation, and this might include children with disabilities or suspected delays.

It's important to be aware of the process of all children and use more individualized practices to teach these skills to children who need more support. And we will talk more about that in the basics. Let’s look at some key ideas. When we're thinking about working with toddlers there's three key ideas we want to think about when supporting problem-solving and relationship skills. The first one is promoting healthy relationships. Educators can model relationship skills with things like sharing or helping or cooperating like you were talking about.

Mike: Yeah.

Becky: Earlier, Mike, with everyone helping you to find your coffee, and providing comfort, and making suggestions in play, and then celebrating each other. That's a big piece of promoting healthy relationships. And teachers can also create developmentally appropriate opportunities for practicing these skills throughout the day, like setting up a space for two or three toddlers to play together at one time. There might be limited space, and limited materials. This way toddlers can practice turn taking and sharing, like we see in this picture on the left.

And we might also start to notice in the toddler years that children could be showing preferences for a particular playmate. This is also a great time to pause and think about what value do we put, or you put, on peer relationships, and how do you expect peers to act with each other? And our awareness of these questions, and our responses to these questions is really supportive of our equitable teaching practices.

Mike: Can I take the middle one?

Becky: Yeah. Yeah!

Mike: Perfect because I love teaching about problem-solving. Conflict happens all the time in case you never have been in an early childhood classroom, but I don't think this — I think this audience knows. Conflicts happen all the time in early childhood environments where children are really just learning to manage their emotions or behavior through co-regulation. Remember, these are the first times that they might be having these types of emotions. They're like, "Whoa! What is going on?”

Toddlers are beginning to reason, and really beginning to understand simple consequences. Educators can describe the problem. We can offer solutions. Then that's how we can support toddlers in trying a couple different new strategies out. Like, how I imagine as I'm looking at this middle photo, I imagine this educator something — I'm trying to channel my inner educator. "I see you reaching out and you're touching Zoa's leg. I wonder if you're wanting some more space. You can say, 'I need some more space please.'"

Becky: Yeah, totally. Thank you so much, Mike. The next key idea we want to talk about is teach problem-solving in the moment. Problem-solving is hard work as we know, and educators can help toddlers use the problem-solving steps in the moment by first being proactive and anticipating social conflicts before they happen.

This might be being close, as we see in this picture on the right, that the educator is close to the child, supporting her through this interaction. We can also provide support by describing steps for solving the problem and modeling them and supporting the child in going through them. We can also generate solutions together and then we can celebrate success.

And, of course, we want to you remember to individualize the strategies you used to provide support on these skills based on the learning characteristics and needs of the children you support. Some children may need the amount of language used to be modified. Some children may need visual cues or gestures paired with verbal language. Some children may need specific feedback on consequences to help them learn the effect of their behavior on the environment. Again, please stay tuned for the basics and we're going to share some more information about providing specific feedback.

Mike: Let's now take a second to pause and watch a clip on teaching problem-solving in the moment and how that might look like with toppers.

[Video begins]

Teacher: Are you guys taking turns? Would you like to have a turn? OK. Cayden's turn. Now, whose turn is it to put one on top?

Cayden: It's Marcos!

Teacher: It's Marcos' turn. Marcos, did you hear that? He said it's your turn.

Marcos: I make a red one.

Teacher: Your turn. Wow! Your turn! Look at how many blocks — you guys, what could you tell Ryan? Say, "Ryan, that was my tower.”

Marcos: Stop!

Ryan: That was my tower.

Teacher: Stop. That was a good word. Look it, we could get our — oh, I took my cards off. Look it, we could use our cards. We could use our cards, Ryan. Ryan, we could use our cards. Look it, what could we do? You could wait and take a turn to knock it down. Look, you have your own tower to knock down. And you guys did such a good job of ignoring him when he knocked your tower down. Nice job.

[Video ends]

Mike: There was so many wonderful moments here that I just loved. Use our Q&A, purple Q&A widget to type in what did you notice, what did you see, what did you want to express? And we'll kick us off. The first thing that I'm just thinking about is that the educator was the proximity of the educator. What's close by to really support and to anticipate — not jump in right away, but just to anticipate a little bit around problem-solving in the moment.

Becky: Yeah. Like, what we're talking about. Being close. I notice that the educator was narrating the turn-taking and supported turn-taking too.

Mike: And even when the block fell, the educator gave the child words to say and then asked for the toddler for their input.

Becky: Yes, giving the child the words to say because sometimes in the moment they don't know what to say. That's really helpful. I also love this idea of having the solution cards close by. That they were within arm's reach. She didn't have to leave the block area to go and get them.

Mike: As we think about educators and being responsive and thinking about everyone in the learning environment, really, I saw the educator also talking to all the children who were involved. It wasn't just to the child who knocked off the block. Talk to all the children involved about what they can do in order to solve this problem moving forward or next time because it will happen again.

Becky: Yes. And the educator provided positive feedback, which I saw come through the chat giving specific feedback and praise and of utilizing the solutions. We also saw that the educator was very attentive. She was calm, and encouraging, and involving everyone. More comments about being calm and a soft tone of voice which makes a huge difference.

Mike: Exactly. As we move through this presentation, and this, our time together, remember to take time — or let's do it right now. Let's take another moment to pause and reflect on these questions that will support equitable teaching practices. I think the three that you mentioned earlier were how do you expect peers to act with one another with each other? Another one that you said was — you remembered it, you said it.

Becky: Yeah, it was think about how do we feel about conflict or disagreement, or debates?

Mike: That reminds me. The last one that you said was do you listen openly to all children when there is a problem. Just keep these in the back of your mind and because we're probably going to revisit this in a little bit.

Becky: Thank you, Mike, for those reflective questions. Let's think about key ideas for problem-solving and relationship skills with infants since it’s slightly different than toddlers. When we think about promoting healthy relationships with infants, that's what the work is all about. It's all about relationships. This means modeling healthy relationships with the infants in your care so they can feel what it feels like to be in a healthy relationship. It also means modeling healthy relationships with other adults in the learning environment, so infants can see what healthy relationships look like.

Educators can create opportunities for infants to play side-by-side and interact with each other like we see in this picture on the left. The two educators are sitting close together with three infants in their laps. The infants are close enough to notice and reach out for each other, and maybe after they're done reading the book, the infants are placed on the carpet together where they can explore the books on their own and with each other.

Mike: When I just think about the other photo, this where it says, "Practice problem-solving." The one on our right, this is about being aware of infants' cues. Remembering that some infants may not give clear or predictable cues. All infants have different temperaments and varying temperaments, and that creates varying abilities to give cues.

Also, think about infants with disabilities or suspected delays. They may not be using behaviors we're typically accustomed to, such as eye gaze or vocalization, especially if they are the only — and especially if we're working with children who are typically neurotypical. It's important for adults to be very intentional about their observations and what behaviors they recognize as cues. Watch for situations that may trigger stress, or conflict, and provide comfort to those infants while describing what the problem is or was and possible solutions.

Narrate what you are doing in the moment to problem solve as you go along. Like in this picture on the right, you might say something like — I always like pretending to say something, you might say something like, "Oh, I see your holding on to this book. And this looks like it might be a problem. You both look very upset. Hmm. How about we try looking at the book together at the table?”

Becky: Right now, let's watch what promoting healthy relationships with infants might look like. As you're watching this clip, please put in the Q&A what you might say to the two infants that would help promote peer relationships.

Teacher 2: Thank you. Do you want to stand up? Do you need a diaper, Ivy? You need a diaper? She actually [Inaudible] because she was doing something at the table.

Teacher 3: Okay. You going back?

Teacher 2: [Inaudible] Wow! Look at you.

Becky: I love this video so much.

Mike: I'm, like, grinning ear-to-ear.

Becky: What did you notice, Mike, about the video?

Mike: I noticed that these two infants are playing next to each other and they're naturally sharing. They're naturally being in community with one another, which involved naturally taking turns, holding, and lifting up the basket.

Becky: It's such a beautiful moment and I love, like you said, the natural turn taking that's happening. As comments are coming into the chat, one of the things I might say to the two children in this video clip are, "Oh, I see you are both using the basket. Look at how you can take turns.”

Mike: Or I would say something like, "Oh, you two are playing next to each other.” Acknowledging this beautiful interaction, with a lot of excitement and warmth in my tone, a voice.

Becky: And yes, the tone of voice is so important because what we say is just as important as how we say it and how we say it is just as important as what we say.

Mike: And I would even say in just say the joy that's happening, because we often don't look at our Black children, our Black boys, as joyful beings. You can tie that all in together.

Becky: There's so much joy happening in this clip, but I think it gives us a both a lot of joy. Let's see in the chat we're having some comments coming in about, "Oh wow, good job sharing," or let's see here, I'm looking, there's so many things that coming up.

Mike: "It's nice to see you two playing together with the basket.”

Becky: "I see you are sitting together, and you are being kind to each other.”

Mike: "Wow, good job sharing.” And that positive tone, once again.

Becky: Yes, lots of comments about — and stating the child's names and how they are sharing the joy. It's wonderful. Keep bringing those in and our wonderful Q&A team will send them out. Mike, I want to hear more about neuroscience now.

Mike: Of course, you do. Research tells us that the early years are foundational. Most important part, especially when brain development, in adults we play a vital role in supporting a healthy brain development, connection and architecture.

In this segment, Neuroscience Nook, we are so excited to connect this research to everyday teaching practices. An important side note before we continue, and as questions using that purple Q&A widget comes in, remember we absolutely want to hear from you. We just don't want to sit here and talk, we want to hear from y'all. If you got questions, comments, concerns, thoughts, ideas, share them with us, or post them in the "Teacher Time" Community in My Peers.

Executive function. The pre-mental cortex begins to develop early on in life. This area of the brain is responsible for what are known as the executive functioning skills. And it's essential for the development of strong and healthy relationships. As you can see on this graphic, it includes so many different things.

Attention, being able to focus on a task. Working memory, being able to remember rules and procedures. Self-regulation and the ability to control impulses which I didn't have last night when I was eating ice cream. Organization, switching between tasks, flexible thinking, problem-solving, planning behavior, decision-making, motivation.

All of these skills are important to problem-solving and heathy relationships. We can help young children, support young children, to start developing this critical relationship building and problem-solving skills through responsive caregiving and affective teaching practices that are responsive to the individual child's needs. Just like we mentioned in our most recent episode of "Teacher Time," in case you missed it you can go back on…

Becky: DTL Push Play, and you can access our first two infant toddler webinars about building relationships and emotional literacy.

Mike: There you go. I always like to throw it to you because I always forget where exactly it is. But yes, just like she said. We encourage you to look back at the last two years guides, Building Relationship with Children Birth to Five, and Emotional Literacy with Children Birth to Five to see more about the importance of nurturing relationships and the impact on the developing minds. Looks like I also have the next slide. Now let's hear from Dr. Juliet Taylor as she described the development of executive functioning skills.

Juliet Taylor: I'm going to show you a graphic of how executive function develops over time. Here's sort of a graphic representation. And one thing to point out is that we are not born with executive function skills in place. We're born with the potential to develop them, or not, depending on our experiences, our neurophysiology, and the interactions between those things.

This graph shows that on the horizontal axis you can see this is ages birth to 80. And notice that there's not an even distribution between the ages. And that is because there are particular peeks in executive function development. You can see skill proficiency on the vertical axis. And I'm going to highlight a couple of areas where you see tremendous growth and executive function skills. And that is really in the preschool ages between three to five. And then in early adolescents to early adulthood, there's another spike in development.

The foundations of executive function are laid down in the earliest months and years of life. And that really happens through basic, sort of serve and return it's sometimes called, or those basic interactions between child and adult that happen over, and over, and over again. And that spike really does happen in the preschool years after children have verbal language.

Becky: This is such a helpful graphic and such a helpful explanation of executive functioning skills. I'm a visual learner, it meets my learning needs.

Mike: Exactly. We are not born with executive function, but we are born with the potential to develop them. That is why our work, whether it's your direct support, or your indirect support, or you're just hanging out in the back. It's so important that our work is with infants and toddlers to create that lifelong success. We can't say it enough to you. What you are doing is important work. I know we tired sometimes but stick with it. We love you. And thank you for being here with us.

Becky: Yes. I second that. I also, from this video, I think about these peeks in executive functioning that there's a peek between three to five years old right after children have verbal language. And toddlers are just entering into that spike in executive functioning skills which is —I love thinking about that and what does that mean, and what does that mean for toddler behavior, and toddler development.

Mike: And the last two things that are really coming up for me in this one is the foundation of executive function is laid out in the very few first months and years of life. Learning is having in the room and right out as soon as you leave. I was like, I don't know how I'm going to work that. The last thing I was thinking of is the importance of serve and return. If you're like, "What is serve and return?” You know where you can find that? In our last webinar that we did.

Becky: In our "Building Relationships with Infants and Toddlers," we talk a lot about serve and return. Now it's time for the basics. We've talked a lot about the importance of problem-solving and relationship skills. Let's shift to looking at practical strategies for how to support these skills with infants and toddlers.

We're going to do that by getting back to the basics. The basics are a collection of strategies that could be used in any setting with infants and toddlers. And the "Teacher Time" basics are behavioral expectations in advance, attend to and encourage positive behavior, scaffold with cues and prompts, increase engagement, create or add challenge, and provide specific feedback.

In this season of "Teacher Time," we have been focusing on two letters of the basics every episode. We hope that you will join us for all of the webinars this season. And remember, if you've missed the last two webinars on building relationships and emotional literacy with infants and toddlers, you can access those on DTL Push Play. We invite you to tune in to our future webinars. There's a registration link in the resource list if you want to sign up for that now so that you can get all of the basics of positive behavior of sorts.

Today, we're going to be looking at examples of C, create, or add challenge and S, specific feedback to support problem-solving and relationship skills. Let's take one look at how we can create or add challenge. When we're thinking about supporting problem-solving and relationship skills, we can add challenge by carefully selecting toys and materials for the learning environment that support taking turns, waiting, and learning how to share.

This might look like putting out a ball track, or a car track, or a toy that naturally supports turn taking where the children have to wait before sending a ball or a car down the track, or where one ball or one car will fit on the track at a time. Or maybe you put out stacking rings and encourage children to stack together since only one ring could be stacked at a time like we see in this picture on the left.

You could also create waiting games with the materials and routines that you have in the learning environment, like waiting to go down the slide or waiting to go through the tunnel like we see in this picture on the right. You might also sing a song while you wait to wash your hands, or like one of our participants said in the beginning, you have a greeting song in the morning where the children have to wait to do their special dance, or their special move until they hear their name.

Mike: I think that is a great segue, it's almost like you've seen this before, into us watching a video of what a waiting game might look like in the learning environment with a toddler. As you watch the video, we invite you to share once again in the Q&A how you see the educator supporting waiting, and what would you do to support toddlers with waiting in your program center?

Teacher 4: OK, one, two, three, go!

Connor: Whee!

Teacher 4: Good job, Connor.

Teacher 5: You want to count? OK. One, two, three, four, five, go!

Teacher 5: Yay! One, two — Oh, she couldn't wait, could she? She just couldn't wait. That's fine. She went on two. That's good. You want to count? Ah! Hailey didn't want to wait either. That's fine.

Mike: You can see right away, like you heard the counting, the toddler is down before they can actually go down the slide.

Becky: And I loved that the educator honored when the toddlers did wait and when they just couldn't wait. And she said, "Oh, she couldn't wait. That's fine.”

Mike: And it looks like someone in our chat just beat us to it before we said that. There's so much waiting to happen in this video in taking turns, waiting at the top of the slide, toddlers waiting for their turn.

Becky: There’s so much and it felt like this was a very natural turn taking game for this group of toddlers. It felt like it was familiar to them. And it felt like it was something that they were enjoying.

Mike: And just thinking about like my own culture being Afro-Caribbean, in my culture we love to give children control over the waiting time. They want to wait until they are down the slide, the first child is down the slide to climb up, they have that control. Or we'll say, "Hey, how many seconds do you think we should wait?” We're giving them that power, that control.

Becky: I love that. The real traces and the agency. We have a few comments coming in from the chat. Just the encouragement and patience from the educator. That there was a countdown as a verbal strategy and we also saw that the educator was giving examples of waiting, like naming who waited and who couldn't wait.

Let’s  think about specific feedback and providing specific feedback is another way that educators can support problem-solving an relationship skills. Providing specific feedback is about naming and acknowledging when you see a child engage in building relationships.

It might sound like, "Oh, you're helping me put on Natalie's coat.” Or "I saw you get a tissue for Kai. That was so kind.” And the key to specific feedback is being specific. Thinking about what you see and what you saw that toddlers or infants do. Educators can also provide specific feedback to a child when they see them taking turns or sharing, or trying to solve a problem, or playing next to each other, or even playing with a child. That might sound like, "Oh look, Nora is watching you. I think she wants to play too.”

And providing specific feedback is a helpful tool to teach children what to do. You might provide feedback on how to be a friend, or how to solve a problem like, "Hmm, I see that you two are frustrated and have a problem. Let get our solution kit for some ideas.” Or you might say, "Oh, you knocked into Lucas because you were running, and you didn't see him. Let's see if he's okay.”

It's about offering specific ideas of what the toddler can do next and then supporting the infants and toddlers with those next steps and those skills. Remember that, again we said this earlier, how feedback is given, including what you say and how to you say it is important and should be individualized to meet the learning characteristics and temperament of each child.

Mike: Do you remember those three questions I asked earlier? Or you asked them and then I reiterated them? Here's where it comes up again. Three questions. How do you expect peers to act with one another? How do you feel about conflict? And do you listen openly to all children? This is where we are going to apply them.

In our segment Small Change Big Impact where we share how small and adjustments to the way we set up our learning environments, modify a curriculum, or engage with children can make a huge difference in a child's learning. We know that children vary in their learning characteristics and how they engage with people, and materials, and learning environment.

These small changes, and these curriculum modifications are made so that the individual child -- they're made thinking about the individual needs of a child in order to promote their engagement, their participation, and we know that children are more engaged when they have opportunities to learn.

Some children might need more highly individualized teaching practices to help them learn problem-solving such as imbedded teaching or intensive individualized teaching, making curriculum modifications based off a child's individual learning needs can be a great place to start to support this engagement.

Today we're going to be focusing on environmental supports like making physical adjustments to the learning environment to promote participation, engagement, learning problem-solving, relationship skills, the two things of today's talk. When you think about the strategies of physical adjustments, I would love for us to consider changing the space, the location, and arrangement of materials, of activities, to really support the needs of individual children. Like, setting up the smallest space, for example, for a few toddlers to sit together and read a book, or a small sensory table where a few children can play together at the same time. Do you got any ideas?

Becky: I think about managing materials and supplies. Materials could be used in many ways to support individual children with problem-solving and relationship skills. We can think about adding in materials, taking out materials, varying materials, and strategically using the materials to support a desired behavior. You might take out some materials to encourage sharing and turn-taking between toddlers, or you might bring in materials that support waiting. Like, we talked about in the basics.

Or maybe, you set up larger items like tumbling mats, or a large balance beam like we see in this picture in the middle where one child is walking at a time and one child takes a turn at a time. You could also bring in materials that are more engaging and fun with two children, like a rocking boat, or a toddler-safe seesaw.

Mike: For our last one, you can always add visual cues. You could add simple ones. You could add complex ones. I don't know. Do you. Individual cues can really promote relationship between peers and problem-solving skills like sharing a hug or giving a high-five.

Once again, check out the viewer's guide for more suggestions and resources on ECLKC. We encourage you to observe each child to see how they engage in specific areas with a group, and with each other. This can help us think about what are some of the best ways to support the child in building peer relationships and problem-solving skills by individualizing the support that you provide and how to you modify the environment.

Once again, viewer's guide has all these information and tips and tricks of the trade. Let's take a break. Well, we're going to take a break. Y'all aren't going to take a break. To watch a video of how an educator intentionally changes the setup of the environment to support her interactions. And of course, whatever comes to your mind, type it into your purple Q&A widget.

Teacher 6: There we go. Are you ready to make soup? Come here. Oops. This one is not broken. We can put water in it. We can hold water. Ready? Oh, Joy wants to do it. Joy, do you want to put some water in here?

Boy: I would.

Teacher 6: You want to help, too? Can you wait one minute? Just wait for Joy's turn? Oh, I don't think she liked that. Can you give it back to Joy, please? Oh!

Teacher 6: What happened?

Mike: This educator knows how much the toddlers at the table loves to play with water. To support this toddler were peer interactions and relationships. The education staff set up the water vents near the dramatic play areas. Did you notice that? Where two toddlers were making soup.

Becky: And as we got to see the children interacted with each other and the soup making moved from the dramatic play area to the table. The educator really supported turn taking at the end of this clip when she narrated what was happening, she used sign language, and asked specifically asked one toddler to give the scoop back to another toddler. We saw a lot of individualizing practices in this video where thinking about a child's interest, thinking about some games that other children were playing, and how we can bring those two together.

Mike: If you are in my classroom, we're making caldo, we're making pozole. But that's neither here or there. Throughout this webinar we have been discussing ways to foster social-emotional skills for all children. Becky, what are we going to talk about more in this segment?

Becky: Thanks, Mike. We're going to think about those reflective questions that we've been mentioning throughout the webinar. In our focus on equity segment, we're going to be using our equity lens to take a closer look at implicit bias and how that impacts how we interact with children and support them in building problem-solving skills, and relationship skills. The value we place on peer relationships and the way we go about building and maintaining them are influenced by our family, our culture, our community, and our experiences.

Sometimes our subtle biases can interfere with our ability to approach conflict between children with an open mind and help them solve problems in a way that is respectful and fair to all children involved. Uncovering these biases take time and reflection. Again, some of these helpful questions to reflect on are — what value do you place on peer relationships? How do you expect peers to act with each other? How do you feel about conflict, disagreements, or debates?

Mike: Do you listen openly to all children when there is a problem?

Becky: And is there a child that you are more likely to make negative assumptions about when a problem involves that specific child? We just encourage you to ask a friend, or a colleague, or a coach to video record you during a time of day when there tends to be more conflict between children. Then go back and watch the video and notice how you respond and interact with each child involved in the conflict. And again, ask yourself, "Does every child receive the support and instruction they need?”

Mike: I am just a little bit excited for this because I'm featured on it. "Teacher Time Library," Emily Small, with someone you clearly recognize that you see in this video, me, Mike Browne, I got to sit with our "Teacher Time" librarian, Emily, and I'm so excited about this month's book. Let's watch me, Emily, make the CASE.

Mike: Welcome to "Teacher Time Library.” My name is Mike Browne. My pronouns are he/him and I'm joined by the wonderful...

Emily Small: Emily Small. And my pronouns are she/her.

Mike: I am so excited to be here today with you all because we have a great selection of books that Emily has curated to be able to share with us today. And it is all centered around our theme of relationships with other children, which is within the social-emotional development domain of our ELOF goals.

Today, we are going to make the case. The CASE, what is that? You might be unfamiliar. You might not. But either way I'm going to refresh your memory. CASE is an acronym that we love to use in order to make connections between the books and what we're trying to hope to achieve within our ELOF domain.

C is pretty simple, C for cookie, also means connecting to ELOF, which is our Early Learning Outcome Frameworks. A, which is about advancing vocabularies. Books are an amazing opportunity. It is both a window, a mirror, and a sliding door into worlds that can really build children's emotional language, vocabulary, and concept development.

S, now this one is a bit of a long one, but it's about supporting engagement. And engagement looks different for each and every single child. Books stirs creativity. It stirs or imagination and by listening to the voices of children, we can really find ways to support them in being active participants not just in their learning, but of their learning environment.

And last but not least we have E. E is about extending the learning well beyond the books. Think about the questions in your curriculum, your provocations, and the activities that you do each and every single day. How can you plan that, so it connects to STEM? How can you use STEM to connect to dramatic play. How can you connect dramatic play to mental health? And so on and so forth because we're all about loving and nurturing the entire child. But that's enough about me, we going to throw it over to these books. And this first one is my favorite, not just because we are matching.

Emily: Yes, we do match today. A quick note before we get into them. I actually borrowed these from my local library. But also, I encourage everyone to check out their local library rather than just having to purchase the items.

Emily: Our first one is "Blocks" by Irene Dickson. We have two friends, Ruby and Benji who are in parallel play with one another in the block area. Benji would really, really like one of Ruby's red blocks and he takes it. And we see what happens next. How they problem solve, how their peer relationship grows, and then we actually have a third friend enter the picture at the end named Guy. There's a chance to make a prediction about what will happen next.

Mike: STEM.

Emily: Yes. We have that nice high gloss cover, we've got "Mine, Mine, Mine, Yours" by Kimberly Gee.

Mike: We hear, "Mine, mine, mine" a lot with toddlers.

Emily: Yes.

Mike: Not so much "Yours," but that's okay.

Emily: We have some great examples in this one of some repetitive phrases on every page. For instance, we have "Jump, jump, jump, bump.”

Mike: That happens.

Emily: All the time. And then we have "Sorry, sorry, sorry.” "That's okay.” But in the pictures, we're seeing a chance for the children to check in on one another.

Mike: And I think that's so important. Especially when we're talking about social-emotional development is that it's not just enough to say, "Sorry," but how are we also coaching in educating our children in order to say, "Hey, check in, what do you think might help them feel better?” We can take it to another level.

Emily: Definitely. That's "Mine, Mine, Mine, Yours.” Then we have this tiny little board book called "The Last Marshmallow.” It's part of the Storytelling Mass series. There's a bunch in this series. I highly recommend them. You can, again, see I borrowed it from my library. And it is a very cold day, just like it is today, and some friends would like two cups of hot chocolate but there's three marshmallows.

Mike: I'm already hearing the STEM, the math right there.

Emily: They each get one but there's one left and they have to problem solve to figure out how they're going to make this fair.

Mike: Oh, like you said, it's a very cold day, give it to me.

Emily: That's the "The Last Marshmallow" by Grace Lin. And then the one we're going to make the case for is "You Hold Me Up" by Monique Gray Smith and Danielle Daniel. This one, I love the illustrations in this book so much. For our connection, our C, this book uses the phrase, "You hold me up when," and then it gives us very specific examples of how people feel connected and respected to one another. For our advanced vocabulary, we see words such as kind, learn, respect, comfort. Those are great words to be using as part of your daily routine with children.

For our S for supporting engagement, the words on the page reference the illustrations but they don't say specifically what's happening. As children are showing interest in them, talk about what is going on in the illustration. We're seeing this family it looks like baking together. You can comment on that.

Mike: You can even talk about how the intergenerational family is well in this one.

Emily: Yes. There's multiple images throughout this book that show intergenerational families. And then for E, extending the learning, one of the other examples they give is "You hold me up when you sing with me," and so, we know that singing is a great thing to do with infants, especially for those early verbal skills. I would encourage you to incorporate some singing and then of course some musical instruments as well.

Mike: You can even point out and say, "Oh, what type of instrument do you think this is?” And it's perfect because there's this book that was written and illustrated by First Nation People. You can talk about Indigenous people and how they're still alive and they're thriving. There's multiple ways to tie in so many key concepts.

Emily: Absolutely. That's "You Hold Me Up" by Monique Gray Smith and Danielle Daniel.

Mike: Now, what we don't have is one of my other favorite books and that's "Kindness Makes Us Strong," which you can always pick up at...

Emily: Your local library. It comes in a really nice big board book format which is great for both reading individually with children or in a group setting.

Mike: Well, I don't know about you, Emily, but I am ready to go read some books...

Emily: Awesome.

Mike: ...to color, to do it all. Maybe not first. Right now, we are going to say goodbye. But until next time, take care of yourselves and we can't wait. We are wrapping up today's episode and I can't wait to check out my local library to see all those great books that they have. Remember to check out the viewer's guide for complete book list. And if you work with toddlers, Emily also made the case for another book not shown here, "Kindness Makes Us Strong.” Again, all the info is in your viewer guide.

Becky: We just want to say thank you so much for joining us today. We are so excited that you are here and I also want to invite you to next months "Teacher Time" webinar, "Problem-Solving and Relationship Skills in Preschool.” And you can find the registration link in your Resource List Widget for the next three "Teacher Time" webinars. Sign up now. We hope to see you there.

We are also excited to let you know about our Dual Language Celebration Week coming up. Please make sure to register for that as well. And that widget is going to pop up on your screen right after we say goodbye. Thank you so much and we just can't wait to see you until next time.

Mike: Happy Black History Month, everyone. Happy Dual Language Learner Celebration Week. Until next time.

Children are born ready to solve problems! Infants and toddlers rely on supportive relationships to learn how to recognize problems and find solutions. Problem-solving involves patience, persistence, and creativity from both the child and the adults in their lives. As infants and toddlers explore their world and engage in play with peers, challenges and conflicts provide opportunities to learn and grow. Discuss practical strategies to foster problem-solving and relationship-building skills with infants and toddlers.

Note: The evaluation, certificate, and engagement tools mentioned in the video were for the participants of the live webinar and are no longer available. For information about webinars that will be broadcast live soon, visit the Upcoming Events section.

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National Centers: Early Childhood Development, Teaching and Learning

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Last Updated: December 18, 2023

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Early Years Careers

Problem solving in Early Years Settings

5th January 2016 by Kelly Leave a Comment

  The role of the practitioner in supporting children’s problem solving skills

Some early years practitioners struggle with the definition of problem solving. It is all about the process of working through ideas to reach a solution. It is also about processing information and evaluating ideas and concepts.

As children are constantly learning new ideas, skills and concepts, these will all help them develop their problem solving skills.  For those working in childcare it is important to remember that problem solving is not an activity it is the process in which children go through to find a solution.

Children need to be able to use their thinking skills and practitioner should encourage children think creatively. As well as all this learning the development of children’s language is fundamental as they need to be able to vocalise their thoughts. The development of language allows children interact with other s and share those ideas to help find the right solution

How can adults help support children’s problem solving skills

  • Asking questions- adults need to use their skills to ask the right questions as these questions may hold the key to helping children solve that problem.
  • Breaking down the task – Adults can help children break the task up to help them solve the problem in smaller steps.
  • Scaffold the child’s learning – be careful not to answer the child’s questions yourself, questions should be open ended this will allow the children think, plan, predict, explain and recall as well as ask questions back.
  • Listen attentively – practitioners should listen to children’s answers as this will show to the child that what they are thinking is important.
  • Try not to overuse questioning.

Acting as an effective model is a key factor when supporting children’s problem solving skills, as children will look to adults for support and guidance.

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The Power of Playful Learning in the Early Childhood Setting

a child playing in a box

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Play versus learning represents a false dichotomy in education (e.g., Hirsh-Pasek & Golinkoff 2008). In part, the persistent belief that learning must be rigid and teacher directed—the opposite of play—is motivated by the lack of a clear definition of what constitutes playful learning (Zosh et al. 2018). And, in part, it is motivated by older perceptions of play and learning. Newer research, however, allows us to reframe the debate as learning via play—as playful learning.

This piece, which is an excerpt from Chapter 5 in  Developmentally Appropriate Practice in Early Childhood Programs Serving Children from Birth Through Age 8, Fourth Edition (NAEYC 2022), suggests that defining play on a spectrum (Zosh et al. 2018, an idea first introduced by Bergen 1988) helps to resolve old divisions and provides a powerful framework that puts  playful learning —rich curriculum coupled with a playful pedagogy—front and center as a model for all early childhood educators. ( See below for a discussion of play on a spectrum.)

This excerpt also illustrates the ways in which play and learning mutually support one another and how teachers connect learning goals to children’s play. Whether solitary, dramatic, parallel, social, cooperative, onlooker, object, fantasy, physical, constructive, or games with rules, play, in all of its forms, is a teaching practice that optimally facilitates young children’s development and learning. By maximizing children’s choice, promoting wonder and enthusiasm for learning, and leveraging joy, playful learning pedagogies support development across domains and content areas and increase learning relative to more didactic methods (Alfieri et al. 2011; Bonawitz et al. 2011; Sim & Xu 2015).

Playful Learning: A Powerful Teaching Tool

problem solving skills early years

This narrowing of the curriculum and high-stakes assessment practices (such as paper-and-pencil tests for kindergartners) increased stress on educators, children, and families but failed to deliver on the promise of narrowing—let alone closing—the gap.  All  children need well-thought-out curricula, including reading and STEM experiences and an emphasis on executive function skills such as attention, impulse control, and memory (Duncan et al. 2007). But to promote happy, successful, lifelong learners, children must be immersed in developmentally appropriate practice and rich curricular learning that is culturally relevant (NAEYC 2020). Playful learning is a vehicle for achieving this. Schools must also address the inequitable access to play afforded to children (see “Both/And: Early Childhood Education Needs Both Play and Equity,” by Ijumaa Jordan.) All children should be afforded opportunities to play, regardless of their racial group, socioeconomic class, and disability if they have been diagnosed with one. We second the call of Maria Souto-Manning (2017): “Although play has traditionally been positioned as a privilege, it must be (re)positioned as a right, as outlined by the  United Nations Convention on the Rights of the Child, Article 31” (785).

What Is Playful Learning?

Playful learning describes a learning context in which children learn content while playing freely (free play or self-directed play), with teacher guidance (guided play), or in a structured game. By harnessing children’s natural curiosity and their proclivities to experiment, explore, problem solve, and stay engaged in meaningful activities—especially when doing so with others—teachers maximize learning while individualizing learning goals. Central to this concept is the idea that teachers act more as the Socratic “guide at the side” than a “sage on the stage” (e.g., King 1993, 30; Smith 1993, 35). Rather than view children as empty vessels receiving information, teachers see children as active explorers and discoverers who bring their prior knowledge into the learning experience and construct an understanding of, for example, words such as  forecast  and  low pressure  as they explore weather patterns and the science behind them. In other words, teachers support children as active learners.

Importantly, playful learning pedagogies naturally align with the characteristics that research in the science of learning suggests help humans learn. Playful learning leverages the power of active (minds-on), engaging (not distracting), meaningful, socially interactive, and iterative thinking and learning (Zosh et al. 2018) in powerful ways that lead to increased learning.

Free play lets children explore and express themselves—to be the captains of their own ship. While free play is important, if a teacher has a learning goal, guided play and games are the road to successful outcomes for children (see Weisberg, Hirsh-Pasek, & Golinkoff 2013 for a review). Playful learning in the form of guided play, in which the teacher builds in the learning as part of a fun context such as a weather report, keeps the child’s agency but adds an intentional component to the play that helps children learn more from the experience. In fact, when researchers compared children’s skill development during free play in comparison to guided play, they found that children learned more vocabulary (Toub et al. 2018) and spatial skills (Fisher et al. 2013) in guided play than in free play.

Self-Directed Play, Free Play

NAEYC’s 2020 position statement on developmentally appropriate practice uses the term  self-directed play  to refer to play that is initiated and directed by children. Such play is termed  free play  in the larger works of the authors of this excerpt; therefore, free play is the primary term used in this article, with occasional references to self-directed play, the term used in the rest of the DAP book.

Imagine an everyday block corner. The children are immersed in play with each other—some trying to build high towers and others creating a tunnel for the small toy cars on the nearby shelves. But what if there were a few model pictures on the wall of what children could strive to make as they collaborated in that block corner? Might they rotate certain pieces purposely? Might they communicate with one another that the rectangle needs to go on top of the square? Again, a simple insertion of a design that children can try to copy turns a play situation into one ripe with spatial learning. Play is a particularly effective way to engage children with specific content learning when there is a learning goal.

Why Playful Learning Is Critical

Teachers play a crucial role in creating places and spaces where they can introduce playful learning to help all children master not only content but also the skills they will need for future success. The science of learning literature (e.g., Fisher et al. 2013; Weisberg, Hirsh-Pasek, & Golinkoff 2013; Zosh et al. 2018) suggests that playful learning can change the “old equation” for learning, which posited that direct, teacher-led instruction, such as lectures and worksheets, was the way to achieve rich content learning. This “new equation” moves beyond a sole focus on content and instead views playful learning as a way to support a breadth of skills while embracing developmentally appropriate practice guidelines (see Hirsh-Pasek et al. 2020).

Using a playful learning pedagogical approach leverages the skill sets of today’s educators and enhances their ability to help children attain curricular goals. It engages what has been termed active learning that is also developmentally appropriate and offers a more equitable way of engaging children by increasing access to participation. When topics are important and culturally relevant to children, they can better identify with the subject and the learning becomes more seamless.

While educators of younger children are already well versed in creating playful and joyful experiences to support social goals (e.g., taking turns and resolving conflicts), they can use this same skill set to support more content-focused curricular goals (e.g., mathematics and literacy). Similarly, while teachers of older children have plenty of experience determining concrete content-based learning goals (e.g., attaining Common Core Standards), they can build upon this set of skills and use playful learning as a pedagogy to meet those goals.

Learning Through Play: A Play Spectrum

As noted previously, play can be thought of as lying on a spectrum that includes free play (or self-directed play), guided play, games, playful instruction, and direct instruction (Bergen 1988; Zosh et al. 2018). For the purposes of this piece, we use a spectrum that includes the first three of these aspects of playful learning, as illustrated in “Play Spectrum Showing Three Types of Playful Learning Situations” below.

The following variables determine the degree to which an activity can be considered playful learning:

  • level of adult involvement
  • extent to which the child is directing the learning
  • presence of a learning goal

Toward the left end of the spectrum are activities with more child agency, less adult involvement, and loosely defined or no particular learning goals. Further to the right, adults are more involved, but children still direct the activity or interaction.

Developmentally appropriate practice does not mean primarily that children play without a planned learning environment or learn mostly through direct instruction (NAEYC 2020). Educators in high-quality early childhood programs offer a range of learning experiences that fall all along this spectrum. By thinking of play as a spectrum, educators can more easily assess where their learning activities and lessons fall on this spectrum by considering the components and intentions of the lesson. Using their professional knowledge of how children develop and learn, their knowledge of individual children, and their understanding of social and cultural contexts, educators can then begin to think strategically about how to target playful learning (especially guided play and games) to leverage how children naturally learn. This more nuanced view of play and playful learning can be used to both meet age-appropriate learning objectives and support engaged, meaningful learning.   

problem solving skills early years

In the kindergarten classroom in the following vignette, children have ample time for play and exploration in centers, where they decide what to play with and what they want to create. These play centers are the focus of the room and the main tool for developing social and emotional as well as academic skills; they reflect and support what the children are learning through whole-group discussions, lessons, and skills-focused stations. In the vignette, the teacher embeds guided play opportunities within the children’s free play.

Studying Bears: Self-Directed Play that Extends What Kindergartners Are Learning

While studying the habits of animals in winter, the class is taking a deeper dive into the lives of American black bears, animals that make their homes in their region. In the block center, one small group of children uses short lengths and cross-sections of real tree branches as blocks along with construction paper to create a forest habitat for black bear figurines. They enlist their friends in the art center to assist in making trees and bushes. Two children are in the writing center. Hearing that their friends are looking for help to create a habitat, they look around and decide a hole punch and blue paper are the perfect tools for making blueberries—a snack black bears love to eat! Now multiple centers and groups of children are involved in making the block center become a black bear habitat.

In the dramatic play center, some of the children pretend to be bear biologists, using stethoscopes, scales, and magnifying glasses to study the health of a couple of plush black bears. When these checkups are complete, the teacher suggests the children could describe the bears’ health in a written “report,” thus embedding guided play within their free play. A few children at the easels in the art center are painting pictures of black bears.

Contributed by Amy Blessing

Free play, or self-directed play, is often heralded as the gold standard of play. It encourages children’s initiative, independence, and problem solving and has been linked to benefits in social and emotional development (e.g., Singer & Singer 1990; Pagani et al. 2010; Romano et al. 2010; Gray 2013) and language and literacy (e.g., Neuman & Roskos 1992). Through play, children explore and make sense of their world, develop imaginative and symbolic thinking, and develop physical competence. The kindergarten children in the example above were developing their fine motor and collaboration skills, displaying their understanding of science concepts (such as the needs of animals and living things), and exercising their literacy and writing skills. Such benefits are precisely why free play has an important role in developmentally appropriate practice. To maximize learning, teachers also provide guided play experiences.

Guided Play

While free play has great value for children, empirical evidence suggests that it is not always sufficient  when there is a pedagogical goal at stake  (Smith & Pellegrini 2008; Alfieri et al. 2011; Fisher et al. 2013; Lillard 2013; Weisberg, Hirsh-Pasek, & Golinkoff 2013; Toub et al. 2018). This is where guided play comes in.

Guided play allows teachers to focus children’s play around specific learning goals (e.g., standards-based goals), which can be applied to a variety of topics, from learning place value in math to identifying rhyming words in literacy activities. Note, however, that the teacher does not take over the play activity or even direct it. Instead, she asks probing questions that guide the next level of child-directed exploration. This is a perfect example of how a teacher can initiate a context for learning while still leaving the child in charge. In the previous kindergarten vignette, the teacher guided the children in developing their literacy skills as she embedded writing activities within the free play at the centers.

Facilitating Guided Play

Skilled teachers set up environments and facilitate development and learning throughout the early childhood years, such as in the following:

  • Ms. Taglieri notices what 4-month-old Anthony looks at and shows interest in. Following his interest and attention, she plays Peekaboo, adjusting her actions (where she places the blanket and peeks out at him) to maintain engagement.
  • Ms. Eberhard notices that 22-month-old Abe knows the color yellow. She prepares her environment based on this observation, placing a few yellow objects along with a few red ones on a small table. Abe immediately goes to the table, picking up each yellow item and verbally labeling them (“Lellow!”).
  • Mr. Gorga creates intrigue and participation by inviting his preschool class to “be shape detectives” and to “discover the secret of shapes.” As the children explore the shapes, Mr. Gorga offers questions and prompts to guide children to answer the question “What makes them the same kind of shapes?”

An analogy for facilitating guided play is bumper bowling. If bumpers are in place, most children are more likely than not to knock down some pins when they throw the ball down the lane. That is different than teaching children exactly how to throw it (although some children, such as those who have disabilities or who become frustrated if they feel a challenge is too great, may require that level of support or instruction). Guided play is not a one-size-fits-all prescriptive pedagogical technique. Instead, teachers match the level of support they give in guided play to the children in front of them.

Critically, many teachers already implement these kinds of playful activities. When the children are excited by the birds they have seen outside of their window for the past couple of days, the teachers may capitalize on this interest and provide children with materials for a set of playful activities about bird names, diets, habitats, and songs. Asking children to use their hands to mimic an elephant’s trunk when learning vocabulary can promote learning through playful instruction that involves movement. Similarly, embedding vocabulary in stories that are culturally relevant promotes language and early literacy development (García-Alvarado, Arreguín, & Ruiz-Escalante 2020). For example, a teacher who has several children in his class with Mexican heritage decides to read aloud  Too Many Tamales  (by Gary Soto, illus. Ed Martinez) and have the children reenact scenes from it, learning about different literary themes and concepts through play. The children learn more vocabulary, have a better comprehension of the text, and see themselves and their experiences reflected. The teacher also adds some of the ingredients and props for making tamales into the sociodramatic play center (Salinas-González, Arreguín-Anderson, & Alanís 2018) and invites families to share stories about family  tamaladas  (tamale-making parties).

Evidence Supporting Guided Play as a Powerful Pedagogical Tool

Evidence from the science of learning suggests that discovery-based guided play actually results in increased learning for all children relative to both free play and direct instruction (see Alferi et al. 2011). These effects hold across content areas including spatial learning (Fisher et al. 2013), literacy (Han et al. 2010; Nicolopoulou et al. 2015; Hassinger-Das et al. 2016; Cavanaugh et al. 2017; Toub et al. 2018; Moedt & Holmes 2020), and mathematics (Zosh et al. 2016).

There are several possible reasons for guided play’s effectiveness. First, it harnesses the joy that is critical to creativity and learning (e.g., Isen, Daubman, & Nowicki 1987; Resnick 2007). Second, during guided play, the adults help “set the stage for thought and action” by essentially limiting the number of possible outcomes for the children so that the learning goal is discoverable, but children still direct the activity (Weisberg et al. 2014, 276). Teachers work to provide high-quality materials, eliminate distractions, and prepare the space, but then, critically, they let the child play the active role of construction. Third, in guided play, the teacher points the way toward a positive outcome and hence lessens the ambiguity (the degrees of freedom) without directing children to an answer or limiting children to a single discovery (e.g., Bonawitz et al. 2011). And finally, guided play provides the opportunity for new information to be integrated with existing knowledge and updated as children explore.

Reinforcing Numeracy with a Game

The children in Mr. Cohen’s preschool class are at varying levels of understanding in early numeracy skills (e.g., cardinality, one-to-one correspondence, order irrelevance). He knows that his children need some practice with these skills but wants to make the experience joyful while also building these foundational skills. One day, he brings out a new game for them to play—The Great Race. Carla and Michael look up expectantly, and their faces light up when they realize they will be playing a game instead of completing a worksheet. The two quickly pull out the box, setting up the board and choosing their game pieces. Michael begins by flicking the spinner with his finger, landing on 2. “Nice!” Carla exclaims, as Michael moves his game piece, counting “One, two.” Carla takes a turn next, spinning a 1 and promptly counting “one” as she moves her piece one space ahead. “My turn!” Michael says, eager to win the race. As he spins a 2, he pauses. “One . . . two,” he says, hesitating, as he moves his piece to space 4 on the board. Carla corrects him, “I think you mean ‘three, four,’ right? You have to count up from where you are on the board.” Michael nods, remembering the rules Mr. Cohen taught him earlier that day. “Right,” he says, “three, four.”

Similar to guided play, games can be designed in ways that help support learning goals (Hassinger-Das et al. 2017). In this case, instead of adults playing the role of curating the activity, the games themselves provide this type of external scaffolding. The example with Michael and Carla shows how children can learn through games, which is supported by research. In one well-known study, playing a board game (i.e., The Great Race) in which children navigated through a linear, numerical-based game board (i.e., the game board had equally spaced game spaces that go from left to right) resulted in increased numerical development as compared to playing the same game where the numbers were replaced by colors (Siegler & Ramani 2008) or with numbers organized in a circular fashion (Siegler & Ramani 2009). Structuring experiences so that the learning goal is intertwined naturally with children’s play supports their learning. A critical point with both guided play and games is that children are provided with support but still lead their own learning.

Digital educational games have become enormously popular, with tens of thousands of apps marketed as “educational,” although there is no independent review of these apps. Apps and digital games may have educational value when they inspire active, engaged, meaningful, and socially interactive experiences (Hirsh-Pasek et al. 2015), but recent research suggests that many of the most downloaded educational apps do not actually align with these characteristics that lead to learning (Meyer et al. 2021). Teachers should exercise caution and evaluate any activity—digital or not—to see how well it harnesses the power of playful learning.

Next Steps for Educators

Educators are uniquely positioned to prepare today’s children for achievement today and success tomorrow. Further, the evidence is mounting that playful pedagogies appear to be an accessible, powerful tool that harnesses the pillars of learning. This approach can be used across ages and is effective in learning across domains.

By leveraging children’s own interests and mindfully creating activities that let children play their way to new understanding and skills, educators can start using this powerful approach today. By harnessing the children’s interests at different ages and engaging them in playful learning activities, educators can help children learn while having fun. And, importantly, educators will have more fun too when they see children happy and engaged.

As the tide begins to change in individual classrooms, educators need to acknowledge that vast inequalities (e.g., socioeconomic achievement gaps) continue to exist (Kearney & Levine 2016). The larger challenge remains in propelling a cultural shift so that administrators, families, and policymakers understand the way in which educators can support the success of all children through high-quality, playful learning experiences.

Consider the following reflection questions as you reflect how to support equitable playful learning experiences for each and every child:

  • One of the best places to start is by thinking about your teaching strengths. Perhaps you are great at sparking joy and engagement. Or maybe you are able to frequently leverage children’s home lives in your lessons. How can you expand practices you already use as an educator or are learning about in your courses to incorporate the playful learning described in this article?
  • How can you share the information in this chapter with families, administrators, and other educators? How can you help them understand how play can engage children in deep, joyful learning?

This piece is excerpted from NAEYC’s recently published book  Developmentally Appropriate Practice in Early Childhood Programs Serving Children from Birth Through Age 8,  Fourth Edition. For more information about the book, visit  NAEYC.org/resources/pubs/books/dap-fourth-edition .

Teaching Play Skills

Pamela Brillante

While many young children with autism spectrum disorder enjoy playing, they can have difficulty engaging in traditional play activities. They may engage in activities that do not look like ordinary play, including playing with only a few specific toys or playing in a specific, repetitive way.

Even though most children learn play skills naturally, sometimes families and teachers have to teach children how to play. Learning how to play will help develop many other skills young children need for the future, including

  • social skills:  taking turns, sharing, and working cooperatively
  • cognitive skills:  problem-solving skills, early academic skills
  • communication skills:  responding to others, asking questions
  • physical skills:  body awareness, fine and gross motor coordination

Several evidence-based therapeutic approaches to teaching young children with autism focus on teaching play skills, including

  • The Play Project:  https://playproject.org
  • The Greenspan Floortime approach: https://stanleygreenspan.com
  • Integrated Play Group (IPG) Model: www.wolfberg.com

While many children with autism have professionals and therapists working with them, teachers and families should work collaboratively and provide multiple opportunities for children to practice new skills and engage in play at their own level. For example, focus on simple activities that promote engagement between the adult and the child as well as the child and their peers without disabilities, including playing with things such as bubbles, cause-and-effect toys, and interactive books. You can also use the child’s preferred toy in the play, like having the Spider-Man figure be the one popping the bubbles.

Pamela Brillante , EdD, has spent 30 years working as a special education teacher, administrator, consultant, and professor. In addition to her full-time faculty position in the Department of Special Education, Professional Counseling and Disability Studies at William Paterson University of New Jersey, Dr. Brillante continues to consult with school districts and present to teachers and families on the topic of high-quality, inclusive early childhood practices.  

Photographs: © Getty Images Copyright © 2022 by the National Association for the Education of Young Children. See Permissions and Reprints online at  NAEYC.org/resources/permissions .

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Toub, T.S., B. Hassinger-Das, K.T. Nesbitt, H. Ilgaz, D.S. Weisberg, K. Hirsh-Pasek, R.M. Golinkoff, A. Nicolopoulou, & D.K. Dickinson. 2018. “The Language of Play: Developing Preschool Vocabulary Through Play Following Shared Book-Reading.” Early Childhood Research Quarterly 45 (4): 1–17.  

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Zosh, J.M., B. Hassinger-Das, T.S. Toub, K. Hirsh-Pasek, & R. Golinkoff. 2016. “Playing with Mathematics: How Play Supports Learning and the Common Core State Standards.” Journal of Mathematics Education at Teachers College 7 (1): 45–49. https://doi.org/10.7916/jmetc.v7i1.787 . 

Zosh, J.M., K. Hirsh-Pasek, E.J. Hopkins, H. Jensen, C. Liu, D. Neale, S.L. Solis, & D. Whitebread. 2018. “Accessing the Inaccessible: Redefining Play as a Spectrum.” Frontiers in Psychology 9: 1–12. https://doi.org/10.3389/fpsyg.2018.01124 . 

Jennifer M. Zosh, PhD, is professor of human development and family studies at Penn State Brandywine. Most recently, her work has focused on technology and its impact on children as well as playful learning as a powerful pedagogy. She publishes journal articles, book chapters, blogs, and white papers and focuses on the dissemination of developmental research.

Caroline Gaudreau, PhD, is a research professional at the TMW Center for Early Learning + Public Health at the University of Chicago. She received her PhD from the University of Delaware, where she studied how children learn to ask questions and interact with screen media. She is passionate about disseminating research and interventions to families across the country.

Roberta Michnick Golinkoff, PhD, conducts research on language development, the benefits of play, spatial learning, and the effects of media on children. A member of the National Academy of Education, she is a cofounder of Playful Learning Landscapes, Learning Science Exchange, and the Ultimate Playbook for Reimagining Education. Her last book, Becoming Brilliant: What Science Tells Us About Raising Successful Children (American Psychological Association, 2016), reached the New York Times bestseller list.

Kathy Hirsh-Pasek, PhD, is the Lefkowitz Faculty Fellow in the Psychology and Neuroscience department at Temple University in Philadelphia, Pennsylvania.  She is also a senior fellow at the Brookings Institution. Her research examines the development of early language and literacy, the role of play in learning, and learning and technology. [email protected]

Vol. 77, No. 2

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problem solving skills early years

  • May 19, 2010

Supporting Thinking Skills From 0-12 Months

Mother gazing at baby

It’s through interactions and experiences with loved and trusted adults that babies begin to make sense of the world. Learn how you can support your baby’s thinking skills from 0-12 months.

Babies learn by using their senses. They explore and discover by touching and mouthing objects, hearing voices and music, and seeing the colorful, fascinating wonder all around them. But the most important part of your child’s early learning experiences is you. It is through interactions and experiences with loved and trusted adults that babies begin to make sense of the world.

In this first year, babies are learning very important concepts. They learn about cause and effect when they shake a rattle and hear a sound, or when they pull on their mother’s glasses and hear her voice (much sterner than usual) tell them not to pull! They learn about size and shape by stacking blocks, mouthing them, and trying to fit them into the correctly-shaped holes. They learn to solve problems when they discover how to turn the crank to get the jack-in-the-box to pop up. They learn about gravity when they drop a spoon from the high chair and look down to the floor to see where it lands. They learn object permanence—that things they can’t see still exist—when they play peek-a-boo or crawl into the next room to find you.

Encourage your baby to explore.

You will see your baby act on her natural curiosity about the people and objects around her as she:

  • Looks carefully at your face
  • Inspects her hands, fingers, feet and toes
  • Rolls to get closer to a person she wants to connect with or to an interesting object
  • Babbles and then waits for your response
  • Looks at and reaches for objects that interest her.
  • Responds to familiar words like baba, mama, dada, night-night, teddy bear, etc.

Your baby’s curiosity reflects a desire to figure out how the people and objects in his world work. You will see your child’s curiosity in action as he:

  • Touches his fingers and toes
  • Bangs and shakes objects to see what they can do
  • Pulls on long hair or earrings
  • Uses sounds, facial expressions and gestures to get your attention
  • Puts things in his mouth
  • Watches things move
  • Follows interesting sounds with his eyes

These actions help babies learn and build their confidence that they can “make things happen.” When children know they can have an impact on the people and objects around them, they feel confident and competent, which is a key part of developing positive self-esteem. In this way, thinking skills and social-emotional skills are tied together.

What you can do:

  • Offer interesting objects to explore—fabrics of various textures, a ball of sticky masking tape, a wooden spoon and a metal one to touch and compare.
  • Respond to her efforts to communicate. Use words to describe what she is experiencing: I see you looking at that ball on the shelf. Let me get that for you.
  • Delight in their discoveries. You found your hands! Look what they can do. You can use them to reach that red ball.
  • Provide the help your child needs to solve problems, such as showing your baby how to get the lid off the container so she can reach the blocks inside. But before you jump in, give her a chance to do it herself first.

Support your baby’s growing memory and ability to understand new ideas. You will see your baby’s memory develop as she:

  • Recognizes familiar people
  • Anticipates routines, for example, grabbing her “blanky” for naptime or crawling to the high chair when she sees you preparing food
  • Responds (turning/smiling) when she hears her name spoken
  • Shows pleasure when given a familiar object like a favorite book of her “lovey”

Your baby’s growing memory also helps her learn that objects and people still exist even when he can’t see them. This concept is called object permanence. You will see this new skill developing when your baby starts to look for hidden objects. This is because he remembers the object and knows it is still around…somewhere. He may also begin to protest when you leave him with a caregiver, even one he knows and loves. This is because he knows you are out there somewhere and naturally, he wants to make you come back!

During this first year your baby is also learning about the concept of cause and effect—that he can make things happen. When he shakes the rattle it makes a sound. When he bats at the mobile it moves. When he cries out for you, you come. Learning to make things happen is the foundation for solving problems. I want dad’s attention. What can I do? I will crawl to him and pull on his leg to let him know I want him to play. Young babies show you how they are now able to make things happen when they:

  • Cry when they need something
  • Drop food off a high chair tray, look down to the floor to see where it goes, and look for you to come pick it up
  • Enjoy repeating a new activity (like pressing a button to see a toy pop up)
  • Reach for a rattle to shake it and make a sound
  • Play disappearing and reappearing games. Play peek-a-boo. Make a simple game of hiding objects to find. This helps develop your child’s memory and teaches him about object permanence.
  • Encourage your child to explore objects and toys in different ways. Touching, banging, shaking, and rolling help children learn about how things work. Talk with your child about what he is doing. “You got the truck to move by pulling the string!”

Help your baby become a good problem-solver.

Babies learn to solve problems by examining and learning about new objects and people they encounter. Then they apply what they have learned to new situations. For example:

  • A 7-month-old has figured out who she knows and who she doesn’t. So she holds her arms out so you will pick her up, but buries her head in your chest when a new person tries to talk to her.
  • An 11-month-old waves bye-bye when her dad puts her in the crib for the night. This is after seeing her parents wave bye-bye to her many times when they leave for work.

Problem-solving is a critical thinking skill that helps babies be successful now, later in school, and the rest of their lives. In the beginning, the problems babies solve seem simple: How do I make the tambourine rattle? How do I make the jack pop up out of the box? But figuring out the answer to these dilemmas requires a lot of thought and trial-and-error. When they are successful, children feel confident and proud, which motivates them to explore and learn more from the people and world around them.

  • Provide support for reaching goals. Watch your baby carefully. See what she is trying to make happen and help her solve the problem. If she is trying to roll over to reach an interesting object, encourage her to go as far as she can and then bring it close enough that she can get it and explore it.
  • Model problem-solving. Take the top off the container and take the blocks out. Then put them back in and let her have a try. Young children learn a lot through imitation.

Explore differences in objects

One of the strategies babies use to figure out how the world works is by putting objects into categories. They notice similar features even among very different objects. A flower, a rattle, and grandpa’s nose are all very different, but they all can be grasped. Babies also notice differences among similar objects. If they are given a piece of furry fabric and a piece of rubber that are the same size, shape and color, babies will pat the fur and squeeze the rubber. This shows they have some idea about how these textures will feel and “should” be touched. (Berger, 166)

  • Take “touching” walks. On your walks together, hold your baby’s hands up to a bumpy tree trunk. Crinkle a leaf and let her listen. Give her a flower petal to touch, or run her hand over tickly grass. Stop and listen together to the cars going by. Talk about what you are seeing and doing.
  • Look at books that put objects into categories. While your baby won’t be able to understand how to sort objects yet, activities like these will help her build this skill over time.

Make everyday activities “teachable moments.”

Children learn so much during daily routines likes feeding, diapering and bath time. For example, during bath time, babies get to explore math and science concepts like empty/full, in/out, wet/dry. Filling and dumping cups help children learn about empty and full, and in and out. When your child makes the rubber duck splash in the tub, she learns about cause and effect. When the duck stays on top of the water but the washcloth sinks, she is learning about floating and sinking.

What You Can Do:

  • Make the most of daily routines. Let your baby help drop clothing into the washing machine. Hand her groceries she can put on the conveyer belt. Sing a song about body parts as you change her diaper. These routine activities are not-so-routine for your growing baby. They teach her how things work.
  • Give your child some everyday “toys”. See how a wooden spoon and a whisk make very different sounds when tapped on a pot lid. Pull a scarf through a cardboard paper towel tube to make the scarf appear and disappear. Let your child feel the difference between the brush used on her hair, and the spiny teeth of the comb. Activities like this give your child the chance to discover the properties and functions of objects, an important part of problem-solving.

What You Can Do

Offer interesting objects to explore.

Such as fabrics of various textures, a ball of sticky masking tape, a wooden spoon and a metal one, smooth balls and bumpy balls.

Respond to her efforts to communicate.

Use words to describe what she is experiencing: I see you looking at that ball on the shelf. Let me get that for you.

Delight in your child’s discoveries.

You found your hands! Look what they can do. You can use them to reach that red ball.

Provide the help your child needs to solve problems

Such as showing your baby how to get the lid off the container so she can reach the blocks inside. Give her a chance, though, to see if she can do it by herself first.

Play disappearing and reappearing games.

Play peek-a-boo. Make a simple game of hiding objects to find. This helps develop your child’s memory and teaches him about object permanence.

Encourage your child to explore objects and toys in different ways.

Touching, banging, shaking, and rolling help children learn about how things work. Talk with your child about what he is doing. You got the truck to move by pulling the string!

Provide support for reaching goals.

Watch your baby carefully. See what she is trying to make happen and help her solve the problem. If she is trying to roll over to reach an interesting object, encourage her to go as far as she can and then bring it close enough that she can get it and explore it.

Model problem-solving.

Take the top off the container and take the blocks out. Then put them back in and let her have a try. Young children learn a lot through imitation.

Take “touching” walks.

On your walks together, hold your baby’s hands up to a bumpy tree trunk. Crinkle a leaf and let her listen. Give her a flower petal to touch, or run her hand over tickly grass. Stop and listen together to the cars going by. Talk about what you are seeing and doing.

Make the most of daily routines.

Let your baby help drop clothing into the washing machine. Hand her groceries she can put on the conveyer belt. Sing a song about body parts as you change her diaper. These routine activities are not-so-routine for your growing baby, as she learns how things work and begins to imitate the activities of the people she loves.

Give your child some everyday “toys”.

See how a wooden spoon and a whisk make very different sounds when tapped on a pot lid. Pull a scarf through a cardboard paper towel tube to make the scarf appear and disappear. Let your child feel the difference between the brush used on her hair, and the spiny teeth of the comb. Activities like this give your child the chance to discover the properties and functions of objects, an important part of problem-solving

Parent-Child Activities that Promote Thinking Skills

Create an obstacle course..

Lay out boxes to crawl through, stools to step over, pillows to jump on top of, low tables to slither under. Describe what your child is doing as he goes through the course. This helps him understand these concepts.

Play red light/green light.

Cut two large circles, one from green paper and one from red. Write “stop” on the red and “go” on the green, and glue them (back to back) over a popsicle stick holder. This is your traffic light. Stand where your child has some room to move toward you, such as at the end of a hallway. When the red sign is showing, your child must stop but when she sees green, she can GO. Alternate between red and green. See if your child wants to take a turn being the traffic light.

Build big minds with “big blocks”.

Gather together empty boxes of all sorts—very big (like a packing box), medium-sized (shirt or empty cereal boxes), and very small (like a cardboard jewelry box). Let your child stack, fill, dump and explore these different boxes. Which can he fit inside? Which are the best for stacking? Can he put the big boxes in one pile and the small boxes in another?

Make a puzzle.

Make two copies of a photo of your child. Glue one of the photos to sturdy cardboard and cut it into three simple pieces. Put the puzzle together in front of your child. Show her the uncut photo. Put them side by side. Wait and watch to see what she will do. Eventually, she will touch or move the puzzle. With your guidance and help, is she able to put it back together?

Frequently Asked Questions

My 18-month-old is obsessed with our remote control. why does she always go back to it, even when i try to distract her with other toys.

Such is the way with toddlers: Their most frustrating behaviors are often both normal and developmentally appropriate. At this age, your child is working very hard to make sense of her world. One of the most important ways she does that is by watching and then imitating what you do. You are her first and most important teacher. She sees you say “thank you” to the grocery clerk so she learns to say “thank you” too. She watches you sweep the floors and she picks up a broom to help. Unfortunately, you can’t turn this desire to imitate on and off. So when your child sees you touching the remote control, she wants to touch it, too. After all, it must be a good thing if you’re doing it!

Why do children love electronics so much?

You’ll notice that many toys designed for children this age have features they can explore through touch, such as buttons and raised textures—just like most electronics. However, toddlers almost always prefer to play with the real life objects they see you using which is why they go for remotes, cell phones, etc. Toddlers are learning that to be successful, they need to find out how things work. And electronics make for very interesting props. After all, playing with buttons on the remote offers the exciting possibility that–poof!–the magical machine will come alive. Think of how empowering and exciting this is for your child. But it can also drive you crazy! So now is the time to make sure that all “off-limits” electronics are child-proofed or kept out of the way of little hands. However, be sure to offer your child other objects or toys with buttons and other gadgets that he can make work.

How can I get my toddler to stop going for off-limits objects?

Unfortunately, toddlers simply lack the self-control necessary to resist the wonderful temptation of electronic gadgets and other off-limits items (like shiny picture frames or pointy plugs that fit so nicely into those holes in the wall). While toddlers can understand and respond to words such as “no”, they don’t yet have the self-control to stop their behavior, or to understand the consequences if they don’t. Patience is important, since after telling your toddler 20 times not to play with the remote, chances are she’ll still go for it again. Most children don’t even begin to master controlling their impulses until about age 2 ½.

If the object your child is after isn’t likely to pose a danger to him (such as a remote control–although the batteries are a danger if she puts them into her mouth), the decision of how to set limits is yours. Some parents choose to keep all of these gadgets out of reach and don’t allow their children to touch them until they are older. Or, you could allow your child to use them under your close supervision, such as having your child turn the TV on when you’re planning to watch a show and turning it off when you’re through. This models for your child that there are times when using this equipment is okay and times when it’s not.

What’s most important is that you recognize your child’s needs (learning cause and effect, imitating you) and help her meet them in ways that are acceptable to you.

My father recently died, and I’ve been dealing with it okay, but I’m not sure what to do concerning my 20-month-old. When we go to my parents’ house, she asks for Pop-Pop and we tell her he’s not home. However, I can’t keep doing this. I don’t want her to forget her grand-dad, but how can you explain to a baby that someone has died?

This must be a difficult time as you cope with your own feelings and try to make sense of it all for your young child. Helping her understand what has happened to Pop-Pop is indeed a challenge, as 20-month-olds can’t comprehend the idea of death, or even that they will never see someone again. At the same time, children are very tuned in to the feelings of the important adults in their lives, so it is likely that your child, no matter how well you’re handling your Dad’s death, understands that something sad has happened. It is important that what she is sensing is acknowledged.

Since a 20-month-old can’t understand death, trying to explain it to her would probably cause her more confusion and anxiety. Instead focus on addressing her feelings. What’s most important for your daughter at this time is for you to say something like, “Pop-pop isn’t here. I miss him too.” At this time she won’t be able to understand more.

As your child gets closer to 3, she will likely start to ask questions about what happened to her grandfather. You can then explain that Pop-pop is not coming back; that he died, which means that his body stopped working. Tell her this happens when people are very old or sick and doctors and nurses can’t make their bodies work anymore. You can explain that Pop-pop couldn’t do things like eat or play outside anymore. This gives her a context she can relate to. If she asks whether Pop-pop will ever come back, you should tell her the truth–that he won’t. If your child asks whether you or she or others that she loves will die, you can explain that your bodies are healthy and strong so you are not going to die now.

How should I answer my child’s questions about where her Pop-pop is?

Answer your daughter’s questions based on what you think she can understand. Start with something along the lines of: “Pop-pop isn’t here. I miss him too.” As your child gets older and her questions get more mature, your responses will change accordingly until you feel you are ready to tell her: “Pop-pop died. That means that his body stopped working and the doctors and nurses couldn’t make him better.”

Keep your responses brief. A mistake many parents make is giving more information than their child can process. On the other hand, some parents are tempted not to talk about a deceased person for fear that it will upset the child or themselves. But, of course, avoiding the topic doesn’t make the memories or feelings go away. It just deprives your child of the opportunity to make sense of the experience.

How can I help her keep the memory of her grandfather alive?

When your daughter is old enough, share photos, tell stories, and draw pictures of Pop-Pop. You can also have her do something in your father’s memory. Send off a balloon that says, “I love you”. Or have her help you plant a rose bush, for instance, if her grandfather loved flowers. Reading books about loss can also be very helpful. Some good books include When a Pet Dies by Fred Rogers (Puffin, 1998), When Dinosaurs Die by Laurie Krasny and Marc Brown (Little Brown & Co., 1998), and About Dying by Sara Bonnett Stein (Walker & Co., 1985).

Does my toddler have a “short attention span” because she won’t sit for a story for more than a minute?

It is perfectly normal for toddlers to not sit still very long–period. Most don’t like to stay in one place for long now that they can explore in so many new ways– by running, jumping and climbing. So, an adult’s idea of snuggling on the couch to hear a story may not be the same idea a toddler has for story-time. You may only be able to read or talk about a few pages in a book at a time.

Here are some ways to engage active children in reading:

  • Read a book at snack times when your child may be more likely to sit for longer.
  • Offer your child a small toy to hold in her hand—such as a squishy ball—to keep her body moving while you read.
  • Read in a dramatic fashion, exaggerating your voice and actions. This often keeps toddlers interested.
  • Get your child active and moving by encouraging her to join in on familiar phrases or words, act out an action in the story, or find objects on the page. These “activities” can help their attention stay focused.
  • Choose stories that have the same word or phrase repeated. The repetition helps toddlers look forward to hearing the familiar phrase again and also develops their memory and language skills. Encourage her to “help” you read when you get to this refrain.
  • Try books that invite action on the part of the child, such as pop-up books, touch-and-feel books, and books with flaps and hidden openings for them to explore.

Browse our full suite of resources on early childhood development.

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Problem Solving Activities for Preschoolers

  • by Colleen Beck
  • October 22, 2021

Amazon affiliate links may be included in this blog post. As an Amazon Influencer, I earn from qualifying purchases.

It can be frustrating when children act without thinking of the consequences. In this blog post, you’ll learn about the development of problem solving in specific parts of our brain, discover important aspects of executive functioning that impact problem solving abilities, how to teach problem solving to preschoolers, and problem solving activities for preschoolers and young children so they can use words instead of the preschooler’s behaviors  or tantrums.

Best of all, many of our favorite fine motor activities for preschoolers support problem solving skills in early childhood.

Problem solving skills in preschool

Problem Solving Activities for Preschoolers

Before we get into the problem solving activities for preschoolers, and specific strategies to use in early childhood, it’s important to understand the development of the problem-solving process in kids. Supporting small children by giving them the skills to be problem solvers takes time and practice. We’ll get to those specific strategies below.

But first, does this scenario sound familiar at all…

I just don’t understand why Johnny keeps throwing the ball in the house. Doesn’t he realized that he could break the window? Johnny is three and he loves to play with his tennis ball in the house. Even though I have told him over and over again that we don’t throw them in the house, I still catch him sneaking them indoors at least once a week. 

Before we can address problem solving by helping kids look at the big picture and coming up with creative solutions for problem solving issues, we need to understand what is happening developmentally. Self-reflection is a challenging cognitive skill, and for young learners! 

Let’s take a better look at the development of problem solving skills…

Development of problem solving skills in preschoolers

Development of Problem Solving Skills

It’s through play, observation of others, and practice that young learners are developing problem solving skills in early childhood .

Problem solving, rational thinking and reasoning are all skills that are controlled by a part of our brain called the prefrontal cortex. Our brains grow exponentially over the first five years of life, but not the part of our brain that helps us with critical thinking and problem solving skills. This part of our brain, called the prefrontal cortex, isn’t fully developed until we turn 25 years old! 

As babies, we are exposed every day to new experiences, but at this age we don’t comprehend how these experiences affect us and those around us. If only children could think through their problems. This resource on executive functioning skills offers more information.

Have you noticed that it can be a bit scary when teenagers get their drivers licenses? They don’t always think of “what might happen.” This is due to their prefrontal cortex not being fully developed. 

But what about our three and four year olds? We know they can count, ask questions and get the cookie off the counter in a very sneaky way when we aren’t looking. In the Early Years study of 2011 called Making decisions, Taking action , they describe the prefrontal cortex entering a rapid period of development, making critical interconnections with our limbic system. (link: )

This study states “The prefrontal cortex pathways that underlie these capacities are unique to human brains and take a long time to mature. Early connections begin in infancy. Between age 3 and 5 years, the prefrontal cortex circuits enter a rapid period of development and make critical interconnections with the limbic system. During adolescence and early adulthood, the neural pathways are refined and become more efficient.”

What is so great about this part of the brain anyway? 

As the prefrontal cortex (that is located behind out eyes) develops over the years, we are able to engage with situations differently, assessing our surroundings in a new way. As we develop these new executive functioning skills, we are able to keep ourselves safe, build friendships and become successful in our careers.

Related, these friendship activities for preschoolers offers ideas and strategies to support social emotional development.

This peer reviewed report competed by Merve Cikili Utyun, called Development Period of Prefrontal Cortex, discusses how amazing this part of our brain is, and how each of the three sections control different aspects of our functioning. It states that: 

“ PFC includes the following Broadman Areas (BA): 8, 9, 10, 11, 12, 44, 45, 46, 47. “The dorsolateral frontal cortex (BA) 9/46 has been functioned in many cognitive process, including processing spatial information, monitoring and manipulation of working memory, the implementation of strategies to facilitate memory, response selection, the organization of material before encoding, and the verification and evaluation of representations that have been retrieved from long-term memory. 

The mid-ventrolateral frontal cortex (BA 47) has implicated cognitive functions, including the selection, comparison, and judgment of stimuli held in short-term and long-term memory, processing non-spatial information, task switching, reversal learning, stimulus selection, the specification of retrieval cues, and the ‘elaboration encoding’ of information into episodic memory.

BA 10, the most anterior aspect of the PFC, is a region of association cortex known to be involved in higher cognitive functions, such as planning future actions and decision-making. BAs 44 and 45, include part of the inferior frontal and these regions’ functions are language production, linguistic motor control, sequencing, planning, syntax, and phonological processing.

Finally, the orbitofrontal cortex mostly (BA 47, 10, 11, 13) in the orbitofrontal cortex has been implicated in processes that involve the motivational or emotional value of incoming information, including the representation of primary (unlearned) reinforcers such as taste, smell, and touch, the representation of learnt relationships between arbitrary neutral stimuli and rewards or punishments, and the integration of this information to guide response selection, suppression, and decision making.” 

Wow! No wonder it takes so long for this part of our brain to fully develop. Problem solving skills in preschoolers take time to develop!

When Johnny is throwing the ball inside the house, he is thinking about what is happening now, in the present. Not what has happened in the past (when he broke the window at grandmas house a year ago) or that breaking a window might happen in the future. 

What are some problem solving techniques?

Solving problems is a skill that all preschoolers need support with. This critical skill doesn’t happen overnight. It takes time and practice to become second nature.

It’s hard for us, as adults, to remember that children ages 3-5 (preschool-aged) don’t yet have the brain capacity to problem solve on their own, or remember what they learned from a situation a week ago. 

Just like when Andrew was painting at the easel and his paintbrush got stuck in the container. Instead of asking for help or trying to “unstick” the brush, he screamed.  Or when Sally and Samantha ran outside to grab the red bouncy ball, Samantha screamed when Sally grabs it first. She didn’t see the other red bouncy ball in the bucket next to the bikes. 

Try some of these problem solving activities for  kids :

Observation- Children need problem solving strategies that they can observe, and then practice in their everyday lives. Let kids see you talk through problems as you “figure out” a solution. This gives children a chance to see a problem-solving approach in real life situations. They get to see problem solving scenarios in action.

Repetition- Repetition supports brain growth in every area of development including problem solving, executive functioning, motor development, language skills and social development.

Multisensory Activities- Children learn best with multi-sensory cues, learning new skills through seeing, touching, hearing and experiencing the skills they are learning. In 2013, the US National Library of Medicine published an article titled  Neuropsychiatr Dis Treat.  stating “The prefrontal cortex acquires information from all of the senses and orchestrates thoughts and actions in order to achieve specific goals.” (link: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3621648/)

Creative Activities- Solving problems is a skill that all preschoolers need support with. It’s hard for us, as adults, to remember they don’t yet have the brain capacity to problem solve on their own. The best way to teach children how to problem solve, it to create activities that support these new skills in a positive way, that their developing brain understands. This letter to future self is one activity to work on goal achievement even at a young age. Preschoolers can draw a picture of what they would like to do or be as an older child or as a teenager or adult.

Problem Solving Activities for Preschool

Here are 3 Simple Ways to Teach Preschoolers to Solve Problems

1.Teaching executive functioning and problem solving skills in everyday situations will support the growth of a child’s prefrontal cortex. For example, these activities that teach executive functioning at the beach show how much thought and preparation goes into building a simple sand castles.

  • Children have to think about how much sand to use, how to keep it standing, how to prevent sand from getting into their eyes and how to create another one if the one they are building falls down.
  • They must create, plan ahead, problem solve when things get tough and communicate to adults and peers for help.

What other activities does your child do on a regular basis that requires all areas of the prefrontal cortex to activate?

2.When children become upset, their emotions become so overwhelming that they can’t think. In order to calm down and problem solve, they need to access a multi sensory way to help them remember how to do that.

Soothing Sammy gives children tactile and visual cues that remind them how to calm down and problem solve in a developmentally appropriate way. They can be reminded of this positive reinforcement with two words “Sammy Time!”

By reading the book about the sweet golden retriever, who understands that everyone feels upset sometimes, children are encouraged to use all of the sensory strategies to calm down. They can talk to Sammy about what is happening and think through their problem to create a solution.

Ashlie’s four year old daughter did just this. She reports: “When Molly was having some big emotions about coloring a picture and needed to calm down, she visited Sammy and returned with a solution to the problem she came up with all on her own (well with Sammy’s help).”

Click here for more information on the Soothing Sammy resources .

3.Problem solving requires us to remember what just happened, what is happening now and what do we want to happen next. A preschoolers brain tends to blend all three of these situations together, not able to communicate any of them until prompted by an adult. And as an adult, we are left “guessing” what our children are thinking about. Visual cues are a wonderful sensory communication tool to support both children and adults in the realm of solving problems.

Using tools like “First/Then” cards to support routine and common situations like transitions and completing tasks. Using visuals clearly communicates what needs to be done, especially if using pictures of real children doing these tasks.

A Final note about problem solving skills in preschool

Solving problems are hard for young children, even teenagers, as their prefrontal cortex isn’t fully developed yet. Using multisensory teaching tools to support brain development, practicing tasks that teach executive functioning skills and using developmentally appropriate tools to help children calm down, will help even the most frustrating moments become a bit less stressful for children and adults. 

As we learn to be more patient with children, understanding that the part of their brain needed to solve problems is just beginning to develop, repeating the same directions over and over again may not be so frustrating. Our children are doing the best they can. It’s up to us to provide them with experiences to help their brains grow and develop. 

problem solving skills early years

Jeana Kinne is a veteran preschool teacher and director. She has over 20 years of experience in the Early Childhood Education field. Her Bachelors Degree is in Child Development and her Masters Degree is in Early Childhood Education. She has spent over 10 years as a coach, working with Parents and Preschool Teachers, and another 10 years working with infants and toddlers with special needs. She is also the author of the “Sammy the Golden Dog” series, teaching children important skills through play.

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EYFS best practice - All about ... problem-solving

Sheila Ebbutt, a freelance consultant and was formerly managing director of BEAM (Be A Mathematician) Tuesday, July 7, 2009

Responding to challenges and finding solutions is not confined to mathematics but arises in all areas of learning, says Sheila Ebbutt.

problem solving skills early years

Mathematics in the EYFS is called Problem Solving, Reasoning and Numeracy. It's an odd title, probably chosen because it has a rhythmic assonance with Knowledge and Understanding of the World and Communication, Language and Literacy. It's odd, first because problem-solving and reasoning are applicable across all learning, not just maths, and second, because maths is about more than numeracy.

My dictionary defines being 'numerate' as 'able to perform arithmetical operations'. But 'mathematics' has a much wider definition: 'the science dealing with measurements, numbers, quantities, and shapes'. That's a gripe of mine, but let's focus on problem-solving and reasoning. Each of the areas of learning could have had 'problem solving, reasoning and ...' added to their titles.

UNPICKING THE EYFS

The Early Years Foundation Stage has a mixture of very clear, brief descriptions of learning development and more complex general ones.

Simple and brief:

'Continue a rhyming string'; 'respond to simple instructions'; 'handle books carefully'; 'recognise numerals 1 to 5'; 'say the number that is one more than a given number'; 'select a particular named shape'; 'use simple tools competently and effectively'; 'notice and comment on patterns'; 'sing a few familiar songs'; 'go backwards and forwards as well as sideways'.

Complex and general:

'Have an awareness and pride in self and as having own identity and abilities'; 'question why things happen, and give explanations'; 'use language for an increasing range of purposes'; 'use talk to connect ideas, explain what is happening and anticipate what might happen next'; 'use writing as a means of recording and communicating'; 'use developing mathematical ideas and methods to solve practical problems'; 'describe solutions to practical problems, drawing on experience, talking about own ideas, methods and choices'; 'explain own knowledge and understanding, and ask appropriate questions of others'; 'collaborate in devising and sharing tasks, including those which involve accepting rules'; 'talk about personal intentions, describing what they were about to do'; 'work creatively on a large or small scale'.

It is easy to allocate the simple descriptions to particular curriculum areas, and these are recognisable discrete skills that we know we have to teach. 'Continue a rhyming string' is language and 'recognise numerals 1 to 5' is maths.

The general descriptions are harder to allocate, unless there are clues like 'mathematical' and 'writing'. These complex statements have embedded in them a problem-solving approach. How do you teach 'question ...', 'collaborate ...', 'pride ...', 'personal intentions ...'? Well, you don't. You have to set up the environment and the ethos that will encourage these things, and support the children with planned interventions.

It's difficult working with such a mix of complex concepts. You know how to approach 'begin to form recognisable letters' and 'select a particular named shape'. You show children how to form letters. You teach them the names of the shapes. But how do you ensure that this develops into 'use writing as a means of recording and communicating' and 'use developing mathematical ideas and methods to solve practical problems'?

What are the children learning?

Clearly, children are learning about shapes and how they move and fit together; about how to manipulate large objects; about relative heights; about hollow and solid shapes; about filling spaces; about the properties of materials. But they are also learning about collaboration and working to a common goal, and about perseverance; and above all, they are setting themselves problems that they have to solve.

The work in the case study below involved a problem-solving chain, each one with its own goal to be set, obstacles to be overcome, and the solution to be found. One goal is to build a tower with tyres, but the problem is how to lift and place the tyres.

Another goal is to fetch the tyres to add to the tower, but the problem is how to get the tyres to the tower. Another goal is to make the tower as tall as possible, but the problem is how to reach the top of the growing tower - and so on.

Seeking solutions to the problems involves analytical reasoning, conscious or unconscious. How do I move the tyre? Turn it into a wheel by putting it on its edge and rolling it.

Later, during circle time, the children talked about their play with the tyres. Although there was not a lot of talk during the activity, just brief and necessary instructions and comments, the children were able to put into words what they had been doing.

THE NATURE OF PROBLEM-SOLVING

Problem-solving is an integral part of everyday provision, an expectation rather than an added extra, and it relies on a 'have a go' ethos. Successful problem solvers have these kinds of strategies:

- setting themselves a goal - recognising there are obstacles in the way of the goal - getting a feel for the nature of the obstacles - having a sense of possible ways of overcoming the obstacles - planning ahead, and predicting what will happen - checking progress as they go - trying out different possibilities in a systematic way - trying different approaches to see which will work best - looking for even better solutions.

Children who feel confident and secure in their surroundings, and free to make choices, are better able to solve problems, both on their own and collaboratively.

Problems can be minor and arise incidentally, or they can be major projects. But the most important thing is for children to set themselves a challenge, or to engage with the challenge that is there, and then to know that they can choose their own ways of solving it. If children are told the problem and then told the method to use to solve it, they are not problem-solving.

To become confident, proficient problem solvers, it stands to reason that children must have access to a wide range of appropriate resources they can use independently.

The ethos of the setting must support their investigations and allow them to move resources between areas of provision. For example, the children working with the tyres knew with confidence that they could move the tyres around, they could fetch a chair, and they could empty into the tower a range of objects at their disposal, without adult intervention. One of the important things about problem-solving is that it involves choice and that children have opportunities to reason and make decisions.

WHY IS PROBLEM-SOLVING IMPORTANT?

Two highly influential thinkers have stressed the importance of problem-solving as a vehicle for learning: Piaget and Vygotsky.

Piaget thought that children under seven saw the world differently from older children and adults, and they need time to explore the world in their own way. These are some of Piaget's key ideas:

- Children need to be in charge of their own learning by choosing their own activities and taking their own time in that exploration.

- We should provide children with materials to explore, such as block play, role-play materials, small-world toys, and so on. We should involve children in planning the uses of these resources, such as setting up a shoe shop or organising a picnic.

- We need to observe children to find out what they are focusing on and what their interests are, and respond to them if they ask for it. Our role as an adult is as a facilitator in their play.

- We should be aware of the stages of learning that children go through so that we can offer appropriate materials and activities for each stage, and note when children become 'ready' for the next stage.

- We should value each child as an individual.

Vygotsky emphasised collaborative and guided problem-solving. He focused on the social aspect of children's learning, and how they develop their thinking skills through shared experiences. This meant that language is a vital tool for thinking and for sharing ideas. He also looked at the roles of older children and adults in influencing learning. These are some of Vygotsky's key ideas:

- Children learn best through active self-directed play.

- Children learn more effectively in collaboration with other children and with adults.

- Our role is to offer help and support in helping children learn how to do things they cannot quite do on their own. Language is very important here.

- We need to observe children to find out where they are on their own learning trajectory.

- We must focus on language, as this is vital in helping children make sense of the world.

- We must be sensitive in how we take part in children's learning. Sometimes we can take the lead and instruct, at other times we will have minimal engagement.

The EPPE (Effective Provision of Pre-School Education) project corroborated Vygotsky's ideas, by finding that quality conversations between adults and children, and children and other children, enhanced children's problem-solving and reasoning skills. The work of the nursery settings in Reggio Emilia also puts into practice Vygotsky's ideas, with children and adults working collaboratively on long and complex projects.

Children's thinking will only develop well if they can spend their time solving problems. As they solve problems, their confidence and self-esteem increases. However, their self-esteem will decline if they fail too often to solve a problem. The role of the adult is so important in providing appropriate help, support, knowledge and skills.

Problem-solving involves reflection and thought. The adult can help by modelling strategies and encouraging children to talk about their methods. Children can develop a range of methods by collaborating with adults and with other children, and by discussing the range of methods.

HELPING CHILDREN BECOME PROBLEM-SOLVERS

- Create an atmosphere where exploration and having a go are more important than getting the right answer or doing the expected thing to please an adult.

- Provide a rich and stimulating environment, with plenty and varied activities, and don't make things too easy for the children.

- Be an opportunist and look for problem-solving possibilities in everyday activities, such as parties, picnics, tidying-up, arriving and leaving, charity events, a new baby, children's own interests.

- Approach everyday activities as problem-solving opportunities. In adult-led guided learning sessions, make sure children have choices within the framework of the objectives of the session. For example, if children are focusing on counting, play an interesting game that involves choices.

- If children ask you to be involved in their problem-solving, prompt them with comments or questions that will help them to continue to grapple with the problem themselves, or supply further resources that will keep the problem with them. A comment or a look can be as effective as questioning. Certainly, asking questions should not be an inquisition, but a collaborative conversation.

What do you think would help you to reach up there?

Mmm ... I don't know ... What have you tried so far?

Why didn't that work? I wonder if there is another way of doing it.

I wonder if we need anything else here to help us.

How does it look now?

I'm not sure I can do it either! Let's have another go.

- In group sessions, encourage children to describe their play, and the problems they tackled and overcame. Invite them to share ideas and thinking to show what they have done.

- If children are becoming frustrated, or if you feel they are on the cusp of new learning, introduce them to a technique or strategy for taking them on to the next step of learning. You can suggest breaking the problem down into smaller steps, or draw their attention to key features or clues.

- On the other hand, also allow children to get into a muddle so they can see that they need to think things through and develop systematic strategies. Don't take the problem away from the children. Healthy confusion is a good starting point for trying to sort things out.

- Make sure that children have long, uninterrupted periods of time at their own self-directed play.

- Observe children regularly to gain insights into their learning. Analyse and interpret these observations to help understand how to support them in their further learning.

For children to engage in and learn from problem-solving, they need to solve problems that they understand, in familiar contexts, where the outcomes matter to them, either on their own or in collaboration with others. They need to have control over the problem-solving process, and the problems should involve knowledge and skills they are confident with. They should have the opportunity to talk about the process, and have adult help to scaffold smaller steps in the process where they need it.

Two boys are playing with the tyres in the outdoor area of the setting. Their play leads them to start piling one tyre on top of the other. There are lots of tyres lying around the grassy area, and gradually they collect them and add them to their growing cylindrical tower.

Two more children join them, but in a different activity. They each find a container - one a bucket and spade and the other a dustpan and brush - and they gather up leaves and twigs and stones and empty them into the growing tyre cylinder.

The children building the tower have difficulty manipulating the tyres, as they are big and unwieldy. They have to turn each one on its edge and try to roll the tyre along. Sometimes another child sees this going on and volunteers to help.

Lifting the tyres increasingly higher is also difficult and reqiures two children, at least. As the tower grows, one child runs off and fetches a chair, puts it up against the tower, and lifts each tyre up on top. Meanwhile, the fillers continue to collect material to put into the central cavity.

Now that the hole is deeper, they add larger items such as lumps of wood and bark from the digging area. There are eight or nine tyres, one on top of the other. The children work at this activity for an hour and a half with no adult intervention. There is an adult observing from time to time and making notes.

problem solving skills early years

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Raleigh Preschool

10 Ways to Strengthen Your Preschooler’s Problem-Solving Skills

As an adult, you make many decisions throughout your day without even thinking twice about some– from setting up the coffee machine at home to avoiding the long line at the drive-thru that can make you late to work to having a difficult but necessary conversation with your partner about finances. These are just a few examples of problem-solving skills and how you adapt to the situations around you and use your skills to exist on personal, professional, and social levels. 

While some problem-solving skills are innate, your ability to access a situation and take a course of action is based on the fact that when you were a child, the adults around you taught you problem-solving skills. Our Raleigh early-childhood development center is sharing our best advice for anyone looking to strengthen their pre-schoolers problem-solving skills. 

How to teach problem solving skills to preschoolers in Raleigh, NC.

What is Problem Solving in Early Childhood?

Problem-solving refers to the ability to find a solution to a problem. For preschool-aged children, this can be difficult to learn if not modeled for them through the appropriate ways to react to the issues they face. 

For instance, if two children are playing with a toy and one pushes the other in an effort to take the toy, this is clearly an inappropriate way to react to the problem. Furthermore, screaming or yelling for the child to give them the toy is also not a proper way to solve the issue. To model mature and proper problem-solving skills, adults around the child should be practicing the concept of sharing, patience, and communication while avoiding physical and emotional reactions when they don’t get what they want.

When the child learns that they can ask the other child, “Can I play with the toy next?” or understand the concept that another child was playing with the toy first, they are exhibiting the ability to problem solve. 

Why is it Important to Develop Problem Solving Skills in Early Childhood?

Children aged 3 to 5 are developmentally experiencing growth in the following areas: 

  • Cognitive 
  • Emotional 
  • Language 
  • Sensory 
  • Motor 

Because this time for preschoolers is so substantial to their intellectual, emotional, and social development, the world around them can seem overwhelming, unfair, intimidating, and even confusing. By modeling and teaching problem-solving skills to preschoolers , they can learn how to react logically, think creatively, communicate their needs, and assess how best to react to a situation at hand. 

How Can You Teach Problem Solving Skills to Your Children?

It is the responsibility of the adults who raise and teach children to provide kids with opportunities to strengthen their problem-solving skills in early childhood. If you are a parent, guardian, childcare provider, or early-childhood educator, it’s important to consider the best strategies for helping little ones adapt to the world around them and learn problem-solving skills. And remember, it can be frustrating when things do not work out as expected for anyone at any age, particularly for preschool-aged children who are just learning to adapt to their surroundings. 

When teaching your preschool-aged child how to problem solve, consider these four steps that are used in early-childhood classrooms : 

  • Identify the problem
  • Brainstorm solutions to the problem
  • Choose and implement one of the solutions
  • Evaluate how that solution resolved the problem

Following this four-step guideline can help the adults in a preschooler’s life address how a child acquires problem-solving techniques to help them navigate through the difficult and everyday situations that arise. 

When teaching problem-solving, focus on developing these key skills that relate to problem-solving: 

  • Lateral thinking
  • Decision-making
  • Communication
  • Persistence
  • Negotiation
  • Logical thinking
  • Analytical thinking

10 Problem-Solving Activities for Preschoolers

You know that you want to guide your child through developing and strengthening strategies for problem-solving, but where do you begin? Our early-childhood development school is sharing some of our favorite ways to incorporate problem-solving activities into your life so that you can teach your child to grow on a personal and social level. 

#1 – Use Everyday Moments

You do not need a textbook or outline of how to teach your preschooler problem-solving. Simply using everyday moments to demonstrate problem-solving techniques is more useful than any “how to” book or homework assignment can teach your child. 

Going to the grocery store, driving in the car, making dinner at home, and cleaning the house are all everyday opportunities to present your child with decisions related to problem-solving. Having your child put ingredients away in the pantry while you cook, asking your child what aisle at the supermarket they think you can find a particular item, or seeing that there is a mess of toys and supplies and directing the child to initiate where they should be placed prior to starting a new activity are ways to integrate problem-solving into everyday moments. 

#2 – Look to the Child for the Solution

As your child grows up, they will not always have you by their side to solve each and every problem that arises. From issues with friends, future relationships, and future careers, the child you raise will one day become an independent adult who needs to problem-solve on their own. 

Asking children to weigh in for solutions to problems as they arise is one way to get them thinking critically early on in life. When a child is taught to not only assess an obstacle but to trust their own decision-making abilities to resolve a problem, they will be better equipped for success as they get older. 

problem solving skills early years

#3 – Solve Mathematical Problems

Mathematics is a great way to engage children at an early age in problem-solving and solution-making activities. Math is logical and non-emotional, having very clear set rules and boundaries with a single solution is one prime example of problem-solving. When children are given age-appropriate mathematical problems and math word problems, they are given opportunities to troubleshoot and follow an order of operation that leads to a solution.

#4 – Ask Open-Ended Questions

As adults, we often find that the most convenient way to get through the day when caring for a preschooler is to complete tasks for them so that we can get on with our busy day. However, it’s important to pause and present your child with the opportunity to find their own solutions to problems they are faced with by using open-ended questions. 

For instance, your child cannot find their favorite pair of shoes. Rather than tear the house apart on your own looking for them, present the child with a question: “Where did you last wear those shoes?” or “When did you last see your shoes?” This requires your child to consider where they last may have placed them. Additionally, a question like, “If we can’t find those shoes right now, you’ll need to choose a different pair to wear so we aren’t late.” guides them toward finding an alternative solution to the problem. 

Giving children the opportunity to find their own solutions to issues that arise by asking open-ended questions equips them with problem-solving skills they will need throughout life when things do not always go as planned. 

problem solving skills early years

#5 – Puzzles and Board Games

Puzzles and board games, much like math equations, allow children to use their cognitive problem-solving abilities to complete tasks in a fun and unique way. Pre-schoolers are often drawn to images and visual learning components as well as interactive play. Putting puzzles together allows for pattern recognition, while board games allow for interactive problem-solving techniques to be utilized through a set of rules. Incorporating puzzles and games into the lives of children are excellent ways to get them to think critically and find solutions that offer immediate results. 

problem solving skills early years

#6 – Read Books and Tell Stories

Books and storytelling are always exceptional ways to build vocabulary and introduce kids to characters and situations outside of their own. When children are given the opportunity to relate to characters and situations, and then address how those characters can react and engage in their conflicts and interpersonal relationships, it not only fosters imagination and creativity but also problem-solving skills. 

#7 – Center Emotions

As adults we understand that while reacting emotionally to a situation is sometimes natural, it does not get us very far when it comes to solving a problem. Children should be taught how to center those emotions, without shame or guilt by providing an alternative to emotional responses. This is often in the form of learning communication and language. 

If your son’s best friend hurt his feelings, he should not be made to feel that he shouldn’t feel how he is feeling. Having your feelings hurt, particularly by a friend, is, well, hurtful, and there should be no shame attached to that feeling. However, when it comes to addressing those hurt feelings to the friend, it would be inappropriate to shout, “I hate you!” or “I don’t want to be your friend anymore!” Rather, providing your preschool-aged child with words and phrases for when their feelings are hurt is essential to emotional and social development. 

Teaching your son to tell his friend, “It hurts my feelings when you say that” or “I get sad when you are mean to me” are great ways to help children not only process their emotional feelings but express them in appropriate ways that lead to a resolution. 

#8 – Model Problem-Solving Behaviors

Children look to the adults in their lives for how to handle the problems they face in the world. If your child sees you politely ask a waiter to return a plate of food that was incorrectly served, they will learn that proper communication, respect, and patience lead to resolution. In contrast, if a child sees their parents speak rudely and blame a waiter for an incorrect order, they will learn that emotional reactions are the way to address problems. As a parent and caretaker, it is your responsibility to use mistakes, obstacles, and hardships as learning opportunities passed on to your preschool-aged children, demonstrating first-hand that non-emotional responses, kindness, and communication are the keys to getting most issues resolved. 

#9 – Break Down Problems into Chunks

As an adult, one of the ways to get through major projects at work is to set up a schedule that breaks down a large-scale project into smaller portions. Using this technique in childhood education and development is a successful way to teach children how doing one small task can lead to an overall greater, larger picture in the long run. Since a large task can seem overwhelming or even impossible, breaking it down into smaller, easily achievable pieces that will eventually lead to the full, complete picture is a wonderful way to help children of any age, but particularly preschool-aged, tackle large issues without feeling the weight of the big picture.

#10 – Utilize Natural Curiosities and Interests 

Using natural, organic opportunities for learning and problem-solving is always one of the best ways to foster creativity as well as logical and analytical thinking. All children are naturally drawn to some interest– whether it’s unicorns, dinosaurs, airplanes, trucks, or the color blue… every child has something that they become naturally drawn to, often to the surprise of their parents. 

For example, maybe every time your daughter sees the mailman drop off the mail, she is fascinated. Maybe her face lit up with interest and excitement to check what was left in the mailbox today. This is an opportunity to ask questions that lead to analytical thinking and problem-solving. Inquiring, “what does the mail carrier drop off at other houses?” or teaching the concept of writing a letter to grandma and how it goes through the mail can continue to foster interests while teaching logical steps, planning, and problem-solving techniques. 

Enroll Your Child in an Interactive Preschool Care System 

It’s no secret that when a child is at preschool age they are naturally curious and soak up all the information around them. By teaching your child problem-solving skills, they are better equipped to handle the everyday struggles the world has to face. However, the professionals at our preschool development center understand that busy working schedules, multiple children, and life’s responsibilities do not always make it easy for parents to dedicate time to fostering and strengthening problem-solving skills in their children. 

If you have a preschool-aged child who will benefit from emotional, social, and personal development related to problem-solving, contact Primary Beginnings to enroll your child in our 5-star preschool program in Raleigh. 

Contact us today at 919-790-6888 for our Spring Forest Rd. location or 919-785-0303 for our North Hills Dr. location, or fill out our contact form below. 

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Early Childhood Education - Virginia​

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Virginia Kindergarten Readiness Program

Advancing Effective Interactions & Instruction

Problem Solving with Others

Problem solving with others.

The skills needed to solve problems are learned just like academic skills – they don’t develop on their own or overnight

One girl hands a teddy bear to another girl who is seated in a preschool classroom

At a Glance

Preschool children are still learning how to effectively resolve disagreements. To do so, they need to take the perspective of another person and understand how their actions impact others. For example, a child is not likely to think about how taking a toy from another child would make that child mad or sad, which stands in the way of finding a safe, fair solution. You can empower children to learn to solve their own problems by helping them to identify the problem, take another child’s perspective, and implement a solution when issues arise.

  • Get to Know This Skill

What It Looks Like

A quick glance at how you can help preschoolers develop their problem-solving skills, practice solving problems.

Encouraging children to think about and practice problem solving can prepare them to come up with solutions in the moment.

Problem Solving During Center Time

Promote children’s problem solving skills by having them think and talk about the issue. Then work with them as they explore and agree on a resolution.

Use Solutions Cards

Using solution cards prompts children to find and accept solutions. Supports like this work to build children’s ability to problem solve.

Child pointing at problem solving cards

CLASSROOM STRATEGIES

Teach, Model, Support

Young children are still learning how to socialize, collaborate, and negotiate with others. With our support, children can learn these valuable skills and work together to find solutions as challenges arise. Learn key strategies you can use to teach social problem solving in advance and support it in the moment.

TRAUMA-INFORMED CARE

The Power of Play

A brief video from the Harvard Center on the Developing Child explores how play in early childhood can reduce stress (including trauma-related stress) and scaffold problem solving.

  • Watch the Video
  • Download Guiding Questions

FAMILY CONNECTION

Families as a Resource

In this article from the Center for Responsive Schools, Carol Davis shares how educators can have conversations with families about problems that occur in the classroom.

  • Read the Article
  • Download the Guiding Questions

CONSIDERING EQUITY

Considering Culture

In this NAEYC webinar, Dr. Isik-Ercan offers transformative yet practical tips educators can use to understand children’s cultural backgrounds and to support children as they encounter and solve social problems.

  • Watch the Webinar

PROBLEM SOLVING THROUGH BOOKS

Share and Take Turns

Written by Cheri J. Meiners, this book provides many opportunities to talk and think about social situations that young children may encounter in the classroom, such as sharing toys or taking turns.

Book page showing children playing and sharing

Activity Cards for Preschool Classrooms

Part of the streamin 3 curriculum, these activity cards provide simple and fun ways you can prompt children to collaborate and solve problems together.

Solve a Problem Activity Card

Solve A Problem

Create typical social scenarios that children can use to brainstorm solutions.

Partner Talk Card

Partner Talk

Invite children to turn to a peer and ask them something about their life.

Dance Party Card

Dance Party

You and children will work together to create a new dance.

People Sort Card

People Sort!

Challenge children to sort themselves by patterns or colors on their clothing.

Get Our Resource Guide

Includes questions and activities to guide your use of the videos, book suggestions, and activity cards featured for each of the Core Skills

ECE Resource Hub

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problem solving skills early years

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Research on early childhood mathematics teaching and learning

  • Survey Paper
  • Open access
  • Published: 23 June 2020
  • Volume 52 , pages 607–619, ( 2020 )

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  • Camilla Björklund   ORCID: orcid.org/0000-0001-5436-537X 1 ,
  • Marja van den Heuvel-Panhuizen 2 , 3 &
  • Angelika Kullberg 1  

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This paper reports an overview of contemporary research on early childhood mathematics teaching and learning presented at recent mathematics education research conferences and papers included in the special issue (2020–4) of ZDM Mathematics Education . The research covers the broad spectrum of educational research focusing on different content and methods in teaching and learning mathematics among the youngest children in the educational systems. Particular focus in this paper is directed to what lessons can be drawn from teaching interventions in early childhood, what facilitates children’s mathematical learning and development, and what mathematical key concepts can be observed in children. Together, these themes offer a coherent view of the complexity of researching mathematical teaching and learning in early childhood, but the research also brings this field forward by adding new knowledge that extends our understanding of aspects of mathematics education and research in this area, in the dynamic context of early childhood. This knowledge is important for future research and for the development of educational practices.

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1 Introduction

Early childhood mathematics education is a rich field of study and practice that includes the provision of stimulating activities and learning environments, organized and orchestrated by teachers, care-takers and other professionals with the aim of offering young children experiences that extend their knowledge and development of mathematical concepts and skills. Generally, early childhood mathematics education involves children aged 3–6 years, but in many countries even the youngest toddlers go to early childhood centres. Therefore, contemporary research on early mathematics education focuses on children from birth until they enter formal schooling in the first grade. To develop this field of research, a strong foundation of theory and methodology is necessary, along with consideration of the practical settings of young children’s learning as well as the societal needs and relevant educational policy frameworks. Moreover, from a didactical perspective, it also requires consideration of the essence of the mathematics to be taught to young children.

High-quality research grounded in theory is necessary for all areas of mathematics education, in order to move forward and contribute to the generation of new knowledge from which the educational practice can benefit. Since there is much evidence that later development in mathematics is laid in the early years (e.g., Duncan et al. 2007 ; Krajewski and Schneider 2009 ; Levine et al. 2010 ), such high-quality research is especially critical for early childhood mathematics education. Research involving young children entails certain challenges that cannot simply be solved by adopting research designs that are used with older students. The aim of gaining deep knowledge of how young children’s mathematical understanding can be fostered places high demands on research methods. As early as 40 years ago, Donaldson ( 1978 ) stated that children act differently in their everyday situations than they do in experiment situations, and this has been confirmed by many others since then. Thus, gaining knowledge about teaching and learning mathematics in the early years requires research that is conducted in various learning environments and that acknowledges that these learning environments are complex, multifaceted, and dynamic.

Research in mathematics education is a relatively recent scientific discipline beginning in the last century (Kilpatrick 2014 ). Investigating young children’s mathematical learning and teaching became part of this discipline much later. Early childhood mathematics has long been the research field of developmental psychology and cognitive sciences. From the studies of mental abilities and thinking in mathematical problem-solving carried out in these disciplines, we have gained knowledge about the influence of working memory and attention span (e.g., Ashcraft et al. 1992 ; Passolunghi and Costa 2016 ; Stipek and Valentino 2015 ), as well as about the role of innate abilities of numerical awareness in children’s mathematical performance (e.g., Butterworth 2005 ; Wynn 1998 ). Yet, these studies lack a deeper investigation of the mathematics that is performed and how it is developed by children. Neither do such investigations address why certain mathematical competencies are important or why some activities stimulate their development and others do not. Contrary to psychological research, mathematics education research has a didactic perspective, which means that it is linked to the perspective of the learning child, the teaching teacher, and the environment offering learning opportunities in which the teaching and learning take place. Above all, didactic research distinguishes itself from psychological research because it deals explicitly with the question of what the mathematics is in early childhood activities, both within and outside formal education.

2 A brief overview of the current field of early mathematics education research

As shown by the many publications on teaching and learning of mathematics in early childhood that have been released in the past few years, this area of mathematics education research has increasingly become a mature discipline. The same is reflected by the special interest groups, working groups, and research fora dedicated to mathematics education in the early years. No self-respecting conference today can afford not to pay attention to the area of early mathematics, and there are now also communities and conferences that focus exclusively on early childhood mathematics education. All these communities and conferences are the epicentres where the latest developments in this field are brought together. To set the scene for research on early childhood mathematics teaching and learning, without it being complete, we first provide a brief overview of recently presented and discussed early mathematics education research. As an orientation point for this overview, we used what has recently been presented by researchers at three international meetings.

2.1 CERME 11 thematic working group (TWG) on early years mathematics

A conference that already has a considerable track record for including early childhood mathematics as a fixed part of its programme is the biennial conference of the European Society for Research in Mathematics Education (ERME). This conference started in 2009 with a Thematic Working Group (TWG) on Early Years Mathematics. Since then, the number of participants in this group has grown consistently. In 2019, this TWG (that is, TWG13) consisted not only of European researchers but also attracted participants from Canada, Japan, and Malawi. The most dominant theme presented there involved studies of children’s emerging number knowledge. Many of these presentations were traditional in design, including giving children tasks that had to be solved both individually when the children were interviewed and when they worked in groups in a classroom setting. Based on these studies, researchers formulated descriptions of the children’s knowledge. Sometimes, learning trajectories could be generated from these empirical observations. However, within this TWG several examples of studies with more innovative designs and research settings were also presented, including different modes of exploring and expressing numbers, which can extend our knowledge of early childhood mathematics education. An example of such research is Bjørnebye’s ( 2019 ) study, in which a dice game including elements of multiple representations and embodiment of counting strategies opened up the possibility of observing how children’s actions and responses reflect their understanding. Other studies investigated how affordances of manipulatives and applications encouraged children to develop new ways of thinking about numbers either by working in a digital environment (Bakos and Sinclair 2019 ) or by using their fingers to represent numbers (Lüken 2019 ; Björklund and Runesson Kempe 2019 ).

A characteristic of the research community gathered at CERME11 TWG13 is that the participants generally had in common an interest in better understanding the mathematical thinking of the child. Therefore, it was considered crucial that research establish clues for how to recognize mathematical thinking in the early years. For this purpose, Sprenger and Benz ( 2019 ) used eye-tracking data, as this platform was considered to contribute to the analysis of children’s perception of structure in the process of determining quantities. Yet, what Sprenger and Benz discovered is that data from technological devices still need to be interpreted, and that other expressions of children’s perceptions and reasoning are necessary assets for drawing valid conclusions.

A further important issue that was present at CERME11 TWG13 was related to teaching practice. Specifically, several presentations addressed the questions of how mathematics education should be orchestrated in early childhood education and what opportunities to learn should be offered to children. For example, Breive ( 2019 ) investigated the link between inquiry-based education and open-ended problem-solving, and the role of the teacher in orchestrating such conditions for mathematical exploration. In her paper, Breive described the teachers’ behaviour in terms of the degrees of freedom offered to the children with respect to their actions related to the mathematical content and context. Based on the data she collected, Breive concluded that teachers’ ways of acting, and the accompanying learning opportunities, should be given more attention within early mathematics education research. Similarly, Vogler ( 2019 ), who observed teacher–child group interactions, concluded that so-called indirect learning (which can be found as a common approach in many preschool settings) may induce an obstacle to learning mathematics embedded in activities if there is not a mutual understanding of what learning content is the aim of the activity. In line with these two studies, other researchers who focused on teachers’ interactions with children also highlighted critical issues for educational practice and supported further research inquiries.

Another source for learning about the latest developments in early childhood mathematics education research is the POEM conferences (Mathematics education perspective on early mathematics learning between the poles of instruction and construction). The latest conference, POEM4, was held in 2018. The presentations published in the conference proceedings (Carlsen et al. 2020 ) all, in one way or another, reflect the question “In what way—and how much—should children be ‘educated’ in mathematics before entering primary school?” This was also the recurring question in the discussions between the participating scholars. Among the contributions, three themes stood out: children’s mathematical reasoning, early mathematics teaching, and parents’ role in children’s mathematical development. There was a strong interest in children’s reasoning abilities and strategies in problem-solving. For example, Tsamir et al. ( 2020 ) investigated how children express their understanding of patterning. For this purpose, the researchers provided preschoolers with patterns to be copied and compared, while observing their strategies. Children’s strategy use was also observed in relation to play situations. Bjørnebye and Sigurjonsson ( 2020 ) observed them in teacher-led outdoor games, while Lossius and Lundhaug ( 2020 ) observed child-initiated play activities. Some researchers used their observations of children’s encounters with mathematical content for theoretical discussions on how to understand children’s meaning-making, for example by taking the semiotic mediation perspective (e.g., Bartolini Bussi 2020 ) or through the lens of attentional processes (Verschaffel et al. 2020 ).

With respect to early mathematics teaching, at POEM4 it was discussed that teachers’ educational work largely concerns how to empower children in the learning process, assuming that children have agency in their learning (Radford 2020 ). Some of the presented studies (e.g., Palmér and Björklund 2020 ) specifically chose children's perspectives and problematized how seriation was made a content for learning in a children’s story. They showed how different manipulatives and tools used in teaching have different implications for what is made possible for the children to learn. A critical but essential notion was expressed by Tzekaki ( 2020 ), who underlined that whether children act and think mathematically and learn mathematical concepts depends on what is defined to be mathematical thinking and acting. In line with this perspective, Keuch and Brandt ( 2020 ) and Bruns et al. ( 2020 ) also raised the issue that teachers’ and student teachers’ knowledge of mathematics in early childhood education affects their readiness to exploit the content in ways that facilitate children’s mathematical learning.

The issue of the knowledge of mathematics in early childhood was also addressed in papers on the role of parents in children’s learning of mathematics. Parents are recognized as young children’s first educators, contributing to their mathematical understanding and skills. One example of this research focus is Lembrér’s ( 2020 ) study. In order to know what experiences children bring with them into preschool education and thus might inform their encounter with mathematics, she investigated what parents value in the mathematics activities in which their children are engaged at home.

2.3 ICME-13 monograph “Contemporary research and perspectives on early childhood mathematics education”

The ICME-13 Monograph “Contemporary research and perspectives on early childhood mathematics education” (Elia et al. 2018 ) is the third source for becoming informed about the state of the art in the field of teaching and learning mathematics in early childhood. This book, which has its foundations in the ICME-13 (International Congress on Mathematical Education) Topic Study Group 1 (TSG1) “Early childhood mathematics education” held in 2016, contains chapters on a broad range of topics grouped into five key themes: pattern and structure, number sense, embodied action and context, technology, and early childhood educators’ professional issues and education.

Within these themes, the domain-overarching theme of pattern and structure played a prominent role. As Mulligan and Mitchelmore ( 2018 ) showed in a series of studies, children’s awareness of mathematical structures turned out to be crucial for acquiring mathematical competence. Particularly children’s structuring skills were found to be critical to developing coherent mathematical concepts and relationships. These findings are in line with Lüken and Kampmann’s ( 2018 ) intervention study with first graders, in which 5 months of explicit teaching of pattern and structure during regular mathematics lessons resulted in significant differences between pre- and post-test arithmetic achievement scores in the intervention group. Moreover, the intervention was most beneficial to the low-achieving children.

The research within the theme number sense examined a large variety of different aspects of number development. For example, there was a study about children’s enumeration skills when making lists for designating and representing collections of objects (Dorier and Coutat 2016 ). Also, attention was paid to the use of numerical finger gestures and other bodily-based communication in order to facilitate the learning process (Rinvold 2016 ), children’s spontaneous focusing on numerosity (SFON) (Rathé et al. 2018 ; Bojorque et al. 2018 ), and the link between writing skills and number development (Adenegan 2016 ). Furthermore, an exploration of children’s ability to operate with numbers revealed that 5-year-olds were able to solve multiplication and division problems when they were presented in familiar contexts (Young-Loveridge and Bicknell 2016 ).

In the theme embodied action and context , Karsli’s ( 2016 ) video-ethnographic research in a pre-kindergarten classroom showed that young children’s hand and body movements hold rich potential for engaging them in mathematics, and underlined the importance of early childhood teachers’ attention to the embodied ways in which children engage with mathematics, with potential for creating teachable moments. Other studies investigated children’s engagement in the context of play. In Henschen’s ( 2016 ) study free play was examined, while Nakken et al. ( 2016 ) compared free with guided play, of which the latter resulted in the children exhibiting deeper mathematical thinking, and engagement with more specific mathematical concepts. Anderson and Anderson ( 2018 ) broadened the scope by investigating children’s learning of mathematics in their home environment. Thom’s ( 2018 ) and Elia’s ( 2018 ) research on geometrical and spatial thinking in early childhood offered further insights into the crucial role of the body and other semiotic resources (language, drawings, and artefacts) by which young children develop and communicate spatial-geometrical thinking. A general conclusion within this theme was that the limited ways in which young children are invited to engage with geometrical, spatial, and measurement concepts undervalue the embodied, gestural, in-context nature of their mathematical thinking.

The theme technology specifically addressed the integration of technology into early childhood mathematics teaching and learning both at school and at home. The focus was mostly on touch-screen tablet-based applications. Because this new technology significantly differs from the traditional physical aid materials, professional development is needed to help educators identify and implement effective uses of these applications. To learn more about the role of the educator (teacher or parent) in the child’s interaction with the software, Baccaglini-Frank ( 2018 ) carried out an analysis of student-software-teacher relations, revealing how the teacher’s goal of helping the children experience success actually limited their development of numerical abilities. The use of technology also opened a window to a new perspective in early childhood mathematics, namely by exposing young children to advanced mathematics such as understanding symmetric transformation (Fletcher and Ginsburg 2016 ) and dealing with large numbers (also in symbolic form) and ordinality (Sinclair 2018 ).

In the theme early childhood educators’ professional issues and education , Cooke and Bruns ( 2018 ) provided a comprehensive overview of the various contributions in TSG1, for which they proposed to distinguish conditions at three levels that influence opportunities for young children to develop mathematical understanding and skills. At the macro level, curricula provide a framework (aims, content to learn, and activities) for mathematics teaching and learning in early childhood, with varying views. Several papers mentioned the tensions regarding new curricula and frameworks that may impose mathematical content rather than allowing the child to develop understanding of mathematical concepts through play. At the meso level, with focus on the teachers’ competence, all involved papers agreed as to the importance that the teacher possess a fundamental understanding of mathematics as the basis for high-quality early mathematics education. However, different studies used different conceptualizations and instruments to measure teachers’ mathematical competence. The micro level refers to the mathematics educational programmes and materials, as well as to the required training for teachers to develop their ability to effectively select and implement such programmes that address children’s mathematical needs (Fritz-Stratmann et al. 2016 ).

In sum, the common themes that stand out from the three international meetings are children’s learning through play, and concerns regarding how to apply content-focused teaching, with or without technology. We found that a great deal of the research is on children’s mathematical thinking and learning, including two main areas concerning children’s emerging number knowledge and children’s learning of patterns. It is noteworthy that in both areas, how children perceive structure or how they manifest structuring abilities were analysed in several of the studies. There were also a number of studies that focused on how finger patterns, gestures, or bodily-based communication may facilitate children’s learning of numbers.

Children’s learning through free or guided play is also a main issue that was discussed. Teachers’ guiding interaction with children in play was shown to contribute more to deeper mathematical thinking and engagement with specific mathematical content. How teaching affects children’s learning opportunities in preschool was furthermore of great concern in several of the studies. A conclusion drawn from this research is that teachers’ ways of acting and the learning opportunities created for children should be given more attention. In what way, and how much, children should be educated before entering primary school remains a central issue.

3 The contributions of this special issue

In this special issue of ZDM Mathematics Education (Issue 2020–4), contemporary research on early childhood mathematics teaching and learning is discussed by researchers from all over the world. The initiative emanated from the 42nd PME conference in Umeå, Sweden (July 2018), where we had the opportunity to organize a Research Forum in which researchers involved in the field of early childhood mathematics education gathered to present and discuss theoretical and methodological challenges and outcomes of studies on learning and teaching arithmetic skills in early years (Björklund et al. 2018 ; Van den Heuvel-Panhuizen 2018 ). The conclusion of the Research Forum was that early childhood mathematics education research is key, but that more efforts are needed to bring together the state of the art within this field as a foundation for moving early childhood mathematics education research forward. This special issue again provides a window into the contemporary field of research on early childhood mathematics teaching and learning. To discuss what this special issue adds to this field and reflect on the challenges that lie ahead for research on early childhood mathematics education, in the next section we synthesize the themes that emerge from the 15 papers included in this special issue. Each theme highlights the papers’ shared knowledge and contributions to research methods. Many papers are related to several themes, but for our discussion we chose those papers that predominantly belong to a particular theme. In total, we identified three recurring themes: the early interventions and their effects, the facilitating factors for learning and development, and the mathematical key concepts that can be observed in children. Together, these themes bring to the fore aspects that are essential for understanding the learning and teaching of mathematics in the early years.

3.1 What lessons can be drawn from interventions?

Research shows that children’s development of mathematical skills and knowledge is often influenced by socio-economic and curricular factors, and by social interaction in both short- and long-term perspectives (Pruden et al. 2011 ). Thus, there is a raised awareness of the impact early childhood education may have on reducing differences in conditions for learning and on increasing and securing equal opportunities for a good foundation in learning for all children. Based on their meta study of early mathematics education research, Duncan et al. ( 2007 ) stated that early intervention counts and numerous references to the same study indicate that this is an important standpoint in research. Why else indulge in the challenging task of researching learning among the youngest in our education systems, if one does not believe that efforts made through teaching are significant for children’s wellbeing and lifelong learning path?

Research on teaching and learning mathematics often shares a common research design in which interventions are implemented (designed, conducted, and the outcomes assessed) with the aim of finding ways to improve teaching practice for the benefit of the learning child, and often to reduce socio-economic inequality. Intervention studies can be objects of research in different ways, focusing on the children’s learning outcomes or the teaching practices. Nevertheless, the goal is to enhance learning through improved teaching. In the papers in this special issue we find efforts to implement well-designed interventions, explicitly focusing on how to teach. Some implement and analyse fine-grained differences in (teaching) actions and the effects on children’s attention to certain content (Paliwal and Baroody 2020 ; Mulligan et al. 2020 ), while others study the effects of attentiveness to children’s experiences and knowledge and the related choices of tasks (Clements et al. 2020 ; Grando and Lopes 2020 ). Nevertheless, essential to studying intervention success or failure is how learning outcomes are measured and interpreted, which is also an important aspect of early childhood mathematics education research (Li et al. 2020 ).

How teaching is framed to present mathematical content to young children, in order for it to be meaningful to them, and in order to be attentive to children’s experiences and knowledge, is investigated and discussed by Grando and Lopes ( 2020 ). Through narratives provided by early childhood teachers, they find insights into how teachers chose to frame the subjects of statistics and probability in ways that engaged children and were responsive to the children’s own experiences, rather than using materials provided by textbooks. Unconventional teaching methods whereby teachers turned their mathematics classroom into a space of creative insubordination are discussed in this paper in relation to the opportunities they offer children to become equipped with critical thinking. The authors argue that the specific content—statistics and probability—demands problematizing activities and experimentation with uncertain outcomes of problems in order to develop probabilistic thinking. This study highlights an essential issue in didactical research: that the content to be taught is not indifferent to how the teaching is designed. The study particularly raises concerns that the design of teaching cannot be random but rather has to be linked to the educational environment and the students attending that particular environment. Consequently, the generalizability of intervention programmes and teaching methods has to be taken into serious consideration if they are to be implemented in different educational settings.

Clements et al. ( 2020 ) set out to investigate the efficacy of implementing an intervention programme in which instructions and progression are grounded in a research-based learning trajectory. Even though the programme itself had previously been found to have positive outcomes for preschool children’s mathematics learning, the goal of the current study was to investigate how to teach in the most successful way. For this purpose, the authors used the same programme but adapted the choices of the tasks’ difficulty level to the children’s current knowledge levels. How to teach was then related to what to teach individual children. Results indicate that skipping difficulty levels to shorten the steps to the learning goals was not successful. This thorough investigation of teaching by adapting the complexity of the content to the child’s ability to learn best what is intended draws attention to the delicate work of teaching in early childhood education. The study supports child-centred approaches that are sensitive to the individual needs and potential of the child, while simultaneously aiming for the learning goals set by the curriculum.

While Clements et al. investigated the effects of an intervention programme covering broader numerical knowledge, Paliwal and Baroody ( 2020 ) aimed to investigate what conditions for learning the cardinality principle are most effective and how subitizing abilities impact on cardinality knowledge achievement. Their efforts were directed towards a fine-grained analysis of how to teach this aspect of the number concept, and what learning processes different approaches elicit in children. What stands out in their study is that they used a highly advanced research design, which allowed them to examine the effects of different ways of directing children’s attention to seeing numbers’ cardinality. In their paper, they point out the importance of directing children’s attention to various ways of seeing numbers’ cardinality, as follows: as a constructing act by adding units to get a number; as an act starting from naming the whole set with a counting word and then differentiating the added units by counting; and a third condition, attending only to single units in a counting act. Thus, their intervention was designed with explicit rigour as to what was made possible for the children to experience, and their investigation concerned the learning outcomes of the different conditions. While this attention in Paliwal and Baroody’s study to the different conditions can at first glance be considered subtle and far from the instruction children encounter in their mathematics education, the study offers insight into the importance of teachers’ awareness of their way of directing children’s attention to certain meanings of the content.

In another paper focusing on the effects of an intervention programme, Mulligan et al. ( 2020 ) analysed children’s written answers to pattern tasks in order to identify differences and changes in their structural awareness. They found a positive effect on the children’s development of awareness of mathematical pattern and structure (AMPS), and showed how the levels changed as an effect of a 37-week intervention programme. Mulligan et al. add to the field of early childhood mathematics knowledge of a particular ability (structural awareness), how it can be identified among young children, and also how the ability changes over a prolonged period of time (during an intervention), which may provide insight into what children actually learn while taking part in an intervention programme.

Children’s learning is of course at the centre of attention in intervention studies, and Li et al. ( 2020 ) pay explicit attention to how to interpret results from a pre- and post-diagnostic test. In their study, Li et al. investigated the development of mathematics problem-solving skills among kindergarteners by analysing their responses to a cognitive diagnostic test. As in most large-scale analyses, it can be shown in quantitative terms how children develop in producing correct answers that indicate growth in knowledge within certain domains that are tested for. However, Li et al. take a step further in their inquiry and illustrate how two children who scored similarly on the cognitive diagnostic test before an intervention had made different progress during the intervention period. Li et al. suggest that the reason for this difference may lie in how children understand and approach tasks, indicating different understanding even though similar answers are produced. Quantitative measures alone do not reveal such differences. The study thus shows the significance of paying attention to how children reason in order to solve a task. Based on their study, Li et al. recommend that children’s learning outcomes from participating in interventions be seen in the light of how the effects of interventions are measured, as it is observed that some developed skills do not endure over time and similar outcomes among children may conceal different learning paths.

3.2 What facilitates children’s learning and development?

Today, it is undisputed that the development of mathematical skills and the teaching of emerging skills in the early years are essential for mathematics education and developmental progress in the long term (Aunio and Niemivirta 2010 ; Duncan et al. 2007 ; Krajewski and Schneider 2009 ). However, in contrast to this perspective, a recent overview of the long-term effects of preschool mathematics education and interventions (Watts et al. 2018 ) challenges this almost taken-for-granted assumption, as most early interventions have a substantial fadeout effect. Thus, there is a need to revisit our current knowledge of teaching and learning, and scrutinize what seems to make a difference. Some of the papers in the special issue particularly consider this issue in their efforts to ascertain what facilitates children’s mathematical learning and development, and focus on influential aspects found in play settings (Reikerås 2020 ; Tirosh et al. 2020 ), verbal communication in teaching practices (Hundeland et al. 2020 ), and the home numeracy environment (Rathé et al. 2020 ).

Hundeland et al. ( 2020 ) raise the question of how children learn to use and understand the canonical language of mathematics, and study this aspect in terms of mathematical discourses taking place in kindergarten teaching sessions. They take a sociocultural stance (see Vygotsky 1987 ), seeing communication as the link between internal communication (thinking) and external communication (interaction). Therefore, children’s opportunities to contribute ideas and arguments are vital for their (mathematical) learning processes. Earlier research has also shown that care-takers’ talk influences not only children’s vocabulary but also, for instance, their spatial problem-solving (Pruden et al. 2011 ). The deeper knowledge that the study by Hundeland et al. ( 2020 ) provides regarding the quantity and quality of mathematical talk in which children are involved, offers us better opportunities also to organize supportive and stimulating conditions for knowledge growth.

What differs in the study by Hundeland et al. compared to most others with similar research questions is their focus on the kind of interaction that the mathematical discourse induces, which, based on the chosen sociocultural theoretical framework, should be crucial for positive learning outcomes. However, what they study and compare is the impact on the mathematical discourse that a certain in-service training has. This places mathematics in the spotlight of mathematics education research. While psychological and cognitive research provides us with important knowledge of mental processes and developmental advancement, studies like the one by Hundeland et al. have a clear direction towards understanding, and not least improving, the conditions for children’s learning and development, either by implementing teachers’ professional development or through curriculum improvements.

It is commonly agreed that young children’s learning is often situated in play. In a large-scale observation study, Reikerås ( 2020 ) conducted a thorough examination of the kind of play in which toddlers engage, for the purpose of learning how play skills may be related to early mathematical skills. It was found that competencies that allow the child to be active in solitary and parallel play, as well as children’s ability to initiate and remain in a play activity, correlated positively with the toddlers’ mathematical skills. The kind of play skills that showed the highest correlation with mathematical skills was their competence to interact in play. General social play skills thus seem to have an impact on mathematical learning, but Reikerås’ study cannot reveal how these are connected or any causal effects. An effort to better understand the interaction going on in toddlers’ play is made by Tirosh et al. ( 2020 ), investigating the challenges toddlers may face as they practise one-to-one correspondence in a playful context, and how different individuals participate in the playful mathematical context. Here, interaction and social skills become one issue with an impact on the learning opportunities arising in the play.

In many cases, the messy context of children’s play is a methodological challenge. It is not possible to control influencing variables to the same extent as in an experimental design. On the other hand, findings from the messy settings are more likely to bring to the fore aspects that were not anticipated, which raises new questions for research and theory development. Design research supports this kind of knowledge contribution, as several cycles are conducted, each developed based on insights from the previous cycle. These cycles adhere to children’s initiatives such as practising one-to-one correspondence in a setting the table task by putting one spoon inside each cup instead of placing one spoon beside each cup (see Tirosh et al. 2020 ); thus, the child is expressing an understanding of the concept, but is expressing it differently than how the task suggests. This highlights the importance of directing attention to instructions used in research studies, and particularly to the language of mathematics and the spatial aspects of props used in a task, related to the possibilities involved as young children interpret and execute a task.

Children take part in cultural life, where today numerical aspects are an inevitable part of the everyday environment. Nevertheless, there are differences in the extent to which children attend to these aspects, and consequently in how they learn the meaning of numbers, graphical representations of numbers, and how to use numbers. A common assumption is that home numeracy environment is a strong factor (LeFevre et al. 2009 ; Skwarchuk et al. 2014 ), which is reflected not least in the abundance of studies regarding socio-cultural background and demographic factors as a pre-cursor for learning progress. Rathé et al. ( 2020 ) put the common assumption to the test—that home environment has an influence on children’s progress in mathematical development—by comparing young children’s tendency to focus spontaneously on numeracy and numerical symbols in their home numeracy environment. Concerning this specific directionality to numbers, which is assumed to have an impact on children’s arithmetic skills in later years (see McMullen et al. 2015 ), based on their study they propose that the home numeracy environment does not seem to have any significant impact.

3.3 What mathematical key concepts can be observed in children?

A great deal of research in the field of early childhood mathematics education studies what mathematics children understand and how this understanding evolves. This knowledge is crucial in designing teaching that contributes to more advanced thinking and problem-solving strategies that support conceptual growth. Therefore, children’s utterances and how they act are the centre of interest for many researchers. Also, in this special issue, much attention is paid to the mathematical key concepts that can be attributed to children’s thinking, resulting in papers addressing children’s understanding of similarity in mathematical objects (Palmér and Van Bommel 2020 ), their understanding and use of structures (Sprenger and Bentz 2020 ; Kullberg and Björklund 2020 ), their understanding of the concept of cardinality and ordinality (Askew and Venkat 2020 ), and the underlying structure of their quantitative competencies (Van den Heuvel-Panhuizen and Elia 2020 ).

Children’s expressions, and how they are allowed to express themselves, are critical for our understanding of the learning of mathematics. Children’s problem posing is one aspect that can tell us about their understanding of mathematics (Cai et al. 2015 ). In the special issue, this is particularly addressed in the paper by Palmér and Van Bommel ( 2020 ), who investigated children’s understanding of similarity in mathematical objects. They analysed how children themselves created tasks in three-dimensional geometry that were similar to a previous problem-solving task they had worked on. It is suggested that this finding sheds light on the children’s interpretation of the specific mathematical features of the original task.

How children perceive structure has been shown to play an important role in how they, for example, determine a number of objects or solve an arithmetic problem (Ellemor-Collins and Wright 2009 ; Resnick 1983 ). In line with these earlier studies, Sprenger and Bentz ( 2020 ) investigated how 5-year-olds perceive structures in visually presented sets. By having the children determine the number of eggs in a 10-egg box while using an eye-tracking device (and recording the children’s utterances and gestures), they were able to analyse the children’s gaze when determining the cardinality of the set, and thereby gain insight into the process of perception. The eye-tracking data showed, for example, that many of the children were able to see structures (e.g. 4 + 1 or 3 + 2) and use them to determine a quantity without having to count all the objects. The authors argue that children’s ability to perceive structures in sets and use them to determine cardinality is central for their further arithmetic learning, as how children perceive sets (e.g., as individual objects, as a composite whole, or in structured part-whole relations) affects the strategies they use for solving arithmetic tasks.

Similar ideas are found in the study by Kullberg and Björklund ( 2020 ), who studied 5-year-olds’ use of finger patterns to structure number relations while solving an arithmetic problem. They identified two major ways of structuring the task: only structuring, and counting and structuring. In the group that both structured using their fingers and counted on some fingers, some ways were found to be more powerful. Children who solved the arithmetic task (3 + _ = 8) by creating a finger pattern of eight raised fingers and simultaneously identifying (‘seeing’) the missing part (5) on two hands (3 + (2 + 3) = 8) were more successful in solving arithmetic tasks, even in a later follow-up assessment. It is suggested that a possible reason for this later success is that these children were able to see numbers as parts included in other numbers, which has been found in earlier research (Resnick 1983 ) to be important for developing arithmetic skills.

Baccaglini-Frank et al. ( 2020 ) also argue that the appropriate use of fingers can contribute to developing children’s number sense. They studied how 4-year-olds interacted (verbally and using finger patterns) when using the application TouchCounts. The app combines multi-touch with audile, visual, and symbolic representation, and several solution strategies are possible, affording the simultaneous experience of, for example, finger patterns on the screen, with the number both seen and spoken. In their paper the authors emphasize how multimodal affordances may encourage children to use different strategies in response to different tasks, and thus experience a broad range of abilities related to number sense, including both cardinality and ordinality.

Askew and Venkat ( 2020 ) examined children’s understanding of the concept of cardinality and ordinality in connection with their awareness of additive and multiplicative number relations. To investigate this topic, first graders (6- and 7-year-olds) in South Africa were asked to position the numerals 1–9 on a bounded 0–10 number line. The children were able to do this in the correct order, with the fewest errors at the upper and lower ends of the number range. Furthermore, evidence was found that awareness of ordinality and that of cardinality develop alongside each other. However, the logarithmic scale, predicted in earlier research, which is considered to indicate a multiplicative structuring of number relationships, was not confirmed in the South African data. Instead, when the numerals grew larger the intervals became more stretched out rather than compressed. In fact, the children’s responses were closer to the linear model, which is considered to indicate an additive structuring of number relationships. Also, the use of unit sizes that did not take into account the length of the number line, together with the underestimation of the position of 5 on the 0–10 line, offered limited evidence of the children’s awareness of the multiplicative structure of the cardinality of numbers. More research is needed to disclose the deep interconnections between children’s understanding of cardinality and ordinality, and their understanding of multiplicative and additive number relations.

Another effort to unravel the complex nature of children’s early number understanding was carried out by Van den Heuvel-Panhuizen and Elia ( 2020 ), investigating the structure of the quantitative competence repertoire of kindergartners. Based on a literature review, they arrived at a model consisting of two constituent parts: quantification (the ability to connect a number to a given collection of objects) and quantitative reasoning (the ability to think and operate with quantities). Quantification was split up into counting and subitizing, and quantitative reasoning into additive and multiplicative reasoning. Although this model is partly in line with models found in earlier research, it also extends previously developed models by including multiplicative reasoning. Data were collected in the Netherlands and Cyprus. A series of confirmatory factor analyses showed that the hypothesized four-factor model fitted the empirical data of the Netherlands, but not those of Cyprus, which clearly challenges the model’s generalizability. A comparison of the component performances in the Dutch sample revealed that, in accordance with other studies, the lowest scores were found for multiplicative reasoning and that the competence of subitizing seems to develop before counting. This was partly confirmed by a statistical implicative analysis at item level. Although this analysis resulted in different implicative chains in the two countries, in both samples the multiplicative reasoning and conceptual subitizing items were found at the top of the chain and the counting and perceptual subitizing items at the end. Also, more research is necessary here, particularly concerning the generalizability of the model to other countries.

4 Future directions for research on early mathematics teaching and learning

After the Research Forum at PME42 we concluded that to move early childhood mathematics education research forward, more efforts are needed to bring together the state of the art within this field. Thus, we proposed a special issue on the theme Research on early childhood mathematics teaching and learning for the purpose of opening up further discussion and inquiry. In this article, the 15 papers included in the special issue are synthesized and discussed in terms of their contribution to the current field of research in early mathematics teaching and learning along with recent research presented at international mathematics education research conferences. Naturally, these do not cover the worldwide field of research, but they at least give a general idea of the current research interests and challenges.

All the papers in this special issue address aspects of early mathematics education and its underlying theories and research methodologies. They share common interests and challenges concerning how to gain knowledge of the youngest children’s mathematical development, and they identify prosperous teaching approaches. Our appeal to researchers participating in the special issue was to cover the broad span of mathematical ideas that are relevant in early childhood education. Nevertheless, we see a strong direction towards research on the learning and teaching of number concepts and basic arithmetic. This is in line with Alpaslan and Erden ( 2015 ) review of early mathematics research published in 2000–2013 in high-ranked scientific journals in the field of mathematics education, in which the most frequently reported research topics were number systems and arithmetic. The same trend is also found in the research addressed in the latest meetings of ICME, ERME, and POEM. We believe further research should widen this scope, and consider and investigate mathematical topics that are currently less highlighted. There is a need for deeper insight into what mathematics means to young children, and also how the foundations can be laid for the domains of spatial and geometric thinking and measurement, as well as for the domains of structures and patterns, data handling, problem-solving and mathematical reasoning.

Moving an educational field forward, however, is not solely based in covering a broad field of content. To strengthen the field, we need to scrutinize the research designs and methods that are used and the knowledge that is generated. Here, new technologies may open up opportunities for designing tools for investigating children’s competencies. However, this initiative goes beyond choosing digital tools or concrete building blocks; it concerns children’s opportunities to express themselves within different environments and make use of tools and manipulatives that may reveal new insights into their competencies and open up for innovative research questions to be posed. What is made available to experience surely has an impact on children’s expressions of knowledge. And expressions in both words and gestures are important keys here to interpreting the youngest children’s knowledge and skills. We can see this in the recent ICME, ERME, and POEM meetings’ presentation of a large variety of research designs and in the papers of this special issue. Many innovative research designs have been developed that allow thorough investigation of children’s mathematical competence and understanding. What we see, for example, is that subtle differences in expression (e.g. gaze, finger use, or ways of posing questions) reveal new and important insights for developing knowledge of children’s mathematical learning. These innovations in methodology allow for the thorough investigation of key features of learning mathematics that go beyond the broad content areas and highlight how mathematical aspects such as cardinality, ordinality, and number structure are experienced by children. Several of the papers in the special issue particularly attend to these aspects, and do so by creating and using new methodologies and technologies.

The consensus in the field of early mathematics education, reflected in the papers and conference presentations, is strong concerning the impact of early interventions on children’s opportunities to thrive as mathematics learners. From longitudinal studies, we know that early knowledge and skills seem to follow through the child’s development; that is, weak mathematical skills in early childhood years are likely to predict weak mathematics performance in later school years (Reikerås and Salomonsen 2019 ; Hannula-Sormunen et al. 2015 ). This means that early intervention and knowledge of how to offer all children a good start for their mathematical learning are essential to the field of early childhood mathematics education. However, it cannot be assumed that simply participating in education, whether it is framed as free or guided play or problem-solving, or stimulating interactive environments, will result in successful learning outcomes, even though most interventions do have a positive impact and most children develop their knowledge to some extent (Wang et al. 2016 ). Common research objectives, therefore, concern intervention implementation, and analyses of children’s learning outcomes from participating in differently designed activities. These studies are of high importance, as they connect the teaching to the learning and provide insights into what seem to be key aspects in the teaching practice. Nevertheless, researching interventions is delicate work, and it is essential to maintain scientific rigor in the design and analysis. Because early childhood education most often takes place in dynamic settings, the conditions under which children learn vary greatly. This diversity is observed in many studies in which children’s engagement in play, both self-initiated and guided, is used as data for analysing their mathematics competencies and learning of mathematics. This phenomenon means that the conditions offered to explore mathematical concepts and principles should be critically examined, along with how learning from interventions is measured and valued. There is a need to determine what works, what seems critical, and what aspects serve as particular challenges. In research, also special attention has to be given to the nature of the teaching practices. What we learn from intervention studies, both those included in the special issue and those in other contemporary research, is the importance of situating research in the current field of knowledge and the context in which the research is conducted. Each study broadens the picture of the teaching–learning relationship, which is by no means one-directional. There are many aspects to consider that potentially influence this relationship, and all of them cannot be included in one study alone.

Early childhood mathematics education research often attends to the opportunities and conditions that are offered for learning. There is no doubt that children’s activities and interaction with others, already from an early age, offer many opportunities to learn mathematical concepts and basic principles, but our ability to discern what children actually learn from the mathematical learning environments offered to them places high demands on the interpretation process. How to understand the processes going on in play and interaction, and what impacts the children’s learning outcomes—what is made possible to learn—often remains an unsolved issue, as the interaction between teacher and children is dynamic, and particularly as play is multidirectional in nature. Studies of interaction in both formal and informal contexts are nevertheless important, as they are conducted in the complex of social and cultural settings that do influence, through norms and individuals’ experiences, what is possible for children to learn.

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Bruns, J., Carlsen, M., Eichen, L., Erfjord, I., & Hundeland, P. S. (2020). Situational perception in mathematics (SPiM)—Results of a cross-country study in Austria and Norway. In M. Carlsen, I. Erfjord, & P. S. Hundeland (Eds.), Mathematics education in the early years. Results from the POEM4 conference, 2018 (pp. 317–332). Cham: Springer.

Butterworth, B. (2005). The development of arithmetical abilities. Journal of Child Psychology and Psychiatry, 46 (1), 3–18. https://doi.org/10.1111/j.1469-7610.2005.00374.x .

Cai, J., Hwang, C., Jiang, C., & Silber, S. (2015). Problem-posing research in mathematics education: Some answered questions and unanswered questions. In F. M. Singer, N. F. Ellerton, & J. Cai (Eds.), Mathematical problem posing: From research to effective practice (pp. 3–34). New York: Springer.

Carlsen, M., Erfjord, I., & Hundeland, P. S. (Eds.). (2020). Mathematics education in the early years. Results from the POEM4 conference, 2018 . Berlin: Springer.

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Cooke, A., & Bruns, J. (2018). Early childhood educators’ issues and perspectives in mathematics education. In I. Elia, J. Mulligan, A. Anderson, A. Baccaglini-Frank, & C. Benz (Eds.), Contemporary research and perspectives on early childhood mathematics education (pp. 267–289). Cham: Springer Nature.

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Elia, I. (2018). Observing the use of gestures in young children’s geometric thinking. In I. Elia, J. Mulligan, A. Anderson, A. Baccaglini-Frank, & C. Benz (Eds.), Contemporary research and perspectives on early childhood mathematics education (pp. 159–182). Cham: Springer Nature.

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Björklund, C., van den Heuvel-Panhuizen, M. & Kullberg, A. Research on early childhood mathematics teaching and learning. ZDM Mathematics Education 52 , 607–619 (2020). https://doi.org/10.1007/s11858-020-01177-3

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Exploring Problem-Solving in Early Years Mathematics | EYFS/KS1

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This webinar will provide headteachers, mathematics leads, teachers and teaching assistants with practical guidance and methods they can use to nurture and develop pupils’ problem-solving skills in early years and KS1 mathematics.

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Webinar Duration: 46 minutes (approx.)

This webinar will provide headteachers, mathematics leads, teachers and teaching assistants with practical guidance and methods they can use to nurture and develop pupils’ problem-solving skills in maths.

Problem-solving has long been at the heart of the mathematics curriculum. Teaching children how to problem solve in mathematics can support children’s ability to critically evaluate, encourage independence and develop their skills in reasoning and creativity. It is also an essential part of developing mastery of the subject.

In this webinar the Association of Teachers of Mathematics (ATM), who aim to support the teaching and learning of mathematics in the UK, will explore strategies that schools can use to approach problem-solving in maths with the youngest pupils which are creative and engaging and reflect a better understanding of the needs of the learner.

  • Understanding how to introduce learning and problem solving in mathematics which supports children’s ability to problem solve and improve critical thinking skills.
  • Recognising successful techniques that can be used in the classroom which improve reasoning in mathematics.
  • Appreciating the importance of making maths problem-solving learning tailored towards the needs of children and ensuring continuous sharing and evaluation of different methods used.
  • Understanding what is meant by ‘problem-solving skills’ and how to nurture an environment which encourages curiosity and positive attitudes.
  • Building a culture which supports teaching and learning through playing and exploring, active learning and creative and critical thinking.

Since 1994, Helen has been an independent educational consultant specialising in developing the teaching and learning of primary mathematics. In July 2014, she completed her doctorate with the University of Roehampton, London. She is interested in engaging all learners mathematically, and how we might nurture effective and supportive learning communities in classrooms in a current educational climate geared to high-stakes testing. Helen is passionate about all children being given opportunities to become confident mathematical thinkers, through the establishment of a classroom culture that nurtures curious learners.

Helen has taught children across the full primary range and has a particular interest and expertise in early years and KS1 mathematics. Her work involves researching and teaching mathematics alongside colleagues in school and contributing to in-service training courses and conferences. Helen is a long-term, active member of the Association of Teachers of Mathematics (ATM).

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Parent Portfolio

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10 Critical Things Parents Should Teach Their Kids As Early As Possible

Posted: September 23, 2023 | Last updated: November 27, 2023

<p>Toddlers are often known for their candid and innocent remarks, but sometimes their comments can lead to awkward and embarrassing situations, especially in public. Here are some of the most hilarious and mortifying things toddlers have said in public, as shared by parents on a popular online forum.</p>

As parents, we play a vital role in shaping our children’s lives and preparing them for the future. From their earliest years, it is crucial to impart valuable life lessons that will lay a strong foundation for their personal and interpersonal growth. By teaching important skills and instilling essential values early on, parents can empower their children to navigate the complexities of life with confidence and resilience.

<p>Teaching children about respect is crucial for fostering healthy relationships and empathy. Encourage them to treat others, regardless of their differences, with kindness and consideration. By modeling respectful behavior and teaching them to appreciate diversity, you will help them develop strong interpersonal skills that will serve them well throughout their lives.</p>

1. The Value of Respect

Teaching children about respect is crucial for fostering healthy relationships and empathy. Encourage them to treat others, regardless of their differences, with kindness and consideration. By modeling respectful behavior and teaching them to appreciate diversity, you will help them develop strong interpersonal skills that will serve them well throughout their lives.

<p><span>One user was advised never to get a credit card or take out a long because that would cause them to end up in debt. However, they acknowledged that that was a surefire way to have zero credit and never be able to get a mortgage, a loan, some medical care, or some jobs nowadays. </span></p>

2. Financial Literacy

Instilling financial literacy from an early age sets the stage for a lifetime of responsible money management. Teach your children the value of saving, budgeting, and distinguishing between needs and wants. Explain the importance of delayed gratification and the concept of earning money through hard work. By equipping them with these skills, you empower them to make informed financial decisions in the future.

<p>One of the most complex parts of motherhood is figuring out where to draw the line between protecting and being a good parent and being overprotective and causing them more harm than good. </p> <p>If kids never get hurt, never fail, never have to do anything for themselves, and never experience any knocks, they will have a rough start to adulthood. It’s hard to watch your kids have to suffer, even in the slightest, but sometimes it’s necessary for their <a href="https://parentportfolio.com/growth-mindset-quotes/">growth and success</a>. Let them get knocked down sometimes so they know what to do. Let them be independent to an extent so they are prepared for adulthood. </p>

3. Emotional Intelligence

Emotional intelligence is a vital life skill that enables individuals to recognize and manage their own emotions, as well as understand and empathize with others. Teach your children to identify and express their feelings in a healthy manner. Encourage open communication and help them develop problem-solving skills to navigate conflicts effectively. By fostering emotional intelligence, you empower your children to build meaningful relationships and cope with challenges.

<p>When trying to figure out what a landlord cannot do, tenants often wonder if their landlord can just come into their home. A landlord must give the tenant at least 24-hour notice before entering the home in many states. However, a landlord may enter a tenant's home without giving proper notice if an emergency occurs, such as a fire or a medical issue.</p>

4. Independence and Responsibility

Nurturing independence and responsibility in children helps them develop self-confidence and self-reliance. Encourage them to take on age-appropriate responsibilities, such as tidying up after themselves, completing chores, and managing their time. Allow them to make decisions and experience the consequences of their actions within safe boundaries. By doing so, you teach them valuable life skills and help them become accountable individuals.

<p>Okay, this is an infuriating business practice, and it’s done to hinder cancellations. Several users confessed to having gym memberships that required cancellation in person. One signed up right before COVID hit years ago. Ultimately, they moved away, and the gym refused to cancel unless it was in person! The user confessed to paying $10 monthly still. Hey buddy, call your bank and stop the payment.</p>

5. The Power of Perseverance

Teaching children the value of perseverance instills resilience and determination. Encourage them to embrace challenges and view failures as learning opportunities. Teach them that success often requires effort, patience, and the ability to bounce back from setbacks. By instilling a growth mindset, you empower your children to develop a resilient attitude toward life’s obstacles.

Fear is a universal human emotion that manifests differently at various stages of life. While children often fear monsters under their beds or the dark, adults grapple with a distinct set of fears that may come as surprising. As we journey through adulthood, our experiences, responsibilities, and changing perspectives shape our fears in unexpected ways....

6. Empathy and Compassion

Empathy and compassion are essential qualities that promote kindness and understanding towards others. Teach your children to put themselves in someone else’s shoes and consider their feelings and perspectives. Encourage acts of kindness and teach them to stand up against bullying or unfair treatment. By fostering empathy, you help create a more inclusive and compassionate society.

<p><span>A user shared their experience as an intern one summer during college. They spent 95% of their time using SAP, importing it into Excel, cleaning data, and finally generating reports. After the first two weeks, he got the hang of the process and wrote Excel formulas to do 99% of the work. He turned a 9-to-5 day into a 1-hour work day and relaxed for the rest of the day.</span></p>

7. Digital Citizenship

In today’s digital age, it is crucial to educate children about responsible online behavior. Teach them about the potential risks of sharing personal information online and the importance of respecting others’ privacy. Encourage critical thinking and guide them to evaluate the credibility of online sources. By teaching digital citizenship, you equip your children with the tools to navigate the online world safely and responsibly.

<p>Many parents encourage their kids to eat their vegetables by exaggerating the benefits, such as claiming that carrots will improve their night vision. While it’s true that carrots contain vitamin A, which is essential for good vision, this lie can lead to misunderstandings and unrealistic expectations. It’s better to educate children about the importance of a balanced diet for overall health and well-being, rather than relying on fictional claims.</p>

8. The Importance of Healthy Habits

Instilling healthy habits in children sets the stage for a lifetime of well-being. Teach them the value of regular exercise, proper nutrition, and sufficient sleep. Encourage them to make healthy food choices and engage in physical activities they enjoy. By teaching them to prioritize their well-being, you empower them to lead a balanced and healthy lifestyle.

The journey of parenthood is filled with countless decisions, from what to feed your child to how to discipline them. In this quest to provide the best upbringing possible, parents sometimes resort to telling their kids well-intentioned lies. These fibs are often spun with the hope of protecting their innocence, boosting their self-esteem, or simply...

9. The Art of Effective Communication

Effective communication is a fundamental skill that contributes to success in all areas of life. Teach your children to express themselves clearly, listen attentively, and practice active communication. Encourage them to use assertive rather than aggressive or passive communication styles. By nurturing their communication skills, you enable them to build strong relationships, resolve conflicts, and articulate their thoughts effectively.

<p>Teach your children problem-solving and critical thinking skills to help them navigate challenges and make informed decisions. Encourage them to analyze situations, brainstorm solutions, and evaluate the consequences of their actions. Foster creativity and open-mindedness, allowing them to explore different perspectives. By equipping them with these skills, you empower them to overcome obstacles and adapt to a rapidly changing world.</p>

10. Problem-Solving and Critical Thinking

Teach your children problem-solving and critical thinking skills to help them navigate challenges and make informed decisions. Encourage them to analyze situations, brainstorm solutions, and evaluate the consequences of their actions. Foster creativity and open-mindedness, allowing them to explore different perspectives. By equipping them with these skills, you empower them to overcome obstacles and adapt to a rapidly changing world.

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Spending your money on some activities and stuff doesn’t always have to mean that you will lose it. On the contrary, following intelligent and wise steps can even get you into a position where spending also means saving. Here are a few helpful tips from an online frugal community. 1. Preventative Maintenance The number-one-voted response...

Creative Ways To Make Money

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<p>One step-parent allowed their 9-year-old stepdaughter to spend hours alone in her room with markers and papers, assuming she was drawing or making a <a href="https://parentportfolio.com/wordless-picture-books/">picture book</a>. However, the parent later discovered that the child had been using the family calendar to make cards for everyone for upcoming holidays and birthdays. Although the parent did not ask the child about it, they were proud of the child’s logic and long-term planning abilities.</p>

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COMMENTS

  1. How to promote problem solving in the early years

    Developing problem solving skills is an area of development early years' practitioners are familiar with, and the importance of developing these problem solving skills is well known, but what exactly are problem solving skills? And how do we encourage children to develop these?

  2. Ten of our favourite early years problem-solving activities

    1) Den-building Den-building is brilliant for problem-solving as it requires creative and critical-thinking, foresight, and planning. It is also a wonderful way to promote sustained shared thinking with your child.

  3. Maths problem-solving

    Maths problem-solving for young children involves them understanding and using two kinds of maths: Maths knowledge - learning and applying an aspect of maths such as counting, calculating or measuring.

  4. Problem-solving and Relationship Skills in Preschool

    Problem-solving and Relationship Skills in Preschool Playful Learning and Joyful Teaching in Preschools Approaches to Learning, Birth to 5 10 Tips for Creating Supportive Environments That Can Prevent Behaviors That Challenge Us Infant/Toddler Approaches to Learning Supporting Infants' and Toddlers' Emotional and Behavioral Self-regulation

  5. Mathematical Problem Solving in the Early Years: Developing

    Mathematical Problem Solving in the Early Years: Developing Opportunities, Strategies and Confidence The first article Mathematical Problem Solving in the Early Years pointed out that young children are natural problem setters and solvers: that is how they learn.

  6. 10 Simple Activities to Teach Your Preschooler Problem Solving

    Cognitive Development During the first years of a child's life, an important set of cognitive skills known as problem-solving abilities are developed. These skills are used throughout childhood and into adulthood. Find out what problem solving is, why it's important and how you can develop these skills with 10 problem-solving games and activities.

  7. Help Your Child Develop Early Math Skills

    Problem-solving. The ability to think through a problem, to recognize there is more than one path to the answer. It means using past knowledge and logical thinking skills to find an answer. ... Math skills are just one part of a larger web of skills that children are developing in the early years—including language skills, physical skills ...

  8. Approaches to Learning: Problem Solving

    Standard. Children attempt a variety of strategies to accomplish tasks, overcome obstacles, and find solutions to tasks, questions, and challenges. Children build the foundation for problem-solving skills through nurturing relationships, active exploration, and social interactions. In infancy, children learn that their actions and behaviors ...

  9. Tips for teaching maths problem-solving in EYFS

    Teaching & Learning Early Years Problem-solving in early maths: 3 simple teaching tips Problem-solving in early maths: 3 simple teaching tips Teaching strategies for problem-solving is one of five approaches recommended by the Education Endowment Foundation to support young children's maths development - and here's how to do it

  10. Mathematical Problem Solving in the Early Years

    The NRICH EY activities These activities have been carefully structured to support adults in understanding how to help children to develop key problem-solving skills. They outline what children might be doing in a rich context and suggest what an adult may say and/or do initially to provoke mathematical activity.

  11. Importance of Problem Solving Skills in your Child

    Here at Early Childhood University, we value the importance of enhancing problem solving skills, creativity and critical thinking. Send your little ones to a school that focuses on a child's holistic development. ... Two's (2½ years to 3½ years) Preschool (3 years to 4 years) Pre-K (4 years to 5 years) Summer Camp Play & Learn; Extra ...

  12. Problem-solving and Relationship Skills with Infants and Toddlers

    And if we model problem-solving skills early on, this will build a foundation of problem-solving and relationship skills that children can build on and will be able to access with adult support as they develop and start to use these skills more independently. ... Research tells us that the early years are foundational. Most important part ...

  13. Problem solving in Early Years Settings

    Try not to overuse questioning. Acting as an effective model is a key factor when supporting children's problem solving skills, as children will look to adults for support and guidance. The role of the practitioner in supporting children's problem solving skills, read more about how adults role

  14. The Development of Problem Solving in Young Children: A Critical

    The Development of Problem Solving in Young Children: A Critical Cognitive Skill Annual Review of Psychology Vol. 62:1-21 (Volume publication date January 2011) First published online as a Review in Advance on September 3, 2010 https://doi.org/10.1146/annurev.psych.031809.130730 Rachel Keen

  15. The Power of Playful Learning in the Early Childhood Setting

    cognitive skills: problem-solving skills, early academic skills communication skills: responding to others, asking questions physical skills: ... Pamela Brillante, EdD, has spent 30 years working as a special education teacher, administrator, consultant, and professor. In addition to her full-time faculty position in the Department of Special ...

  16. Supporting Thinking Skills From 0-12 Months

    Let your child feel the difference between the brush used on her hair, and the spiny teeth of the comb. Activities like this give your child the chance to discover the properties and functions of objects, an important part of problem-solving. Parent-Child Activities that Promote Thinking Skills Create an obstacle course.

  17. Problem Solving Activities for Preschoolers

    Self-reflection is a challenging cognitive skill, and for young learners! Let's take a better look at the development of problem solving skills… Development of Problem Solving Skills It's through play, observation of others, and practice that young learners are developing problem solving skills in early childhood.

  18. EYFS best practice

    EYFS best practice - All about ... problem-solving. Sheila Ebbutt, a freelance consultant and was formerly managing director of BEAM (Be A Mathematician) Tuesday, July 7, 2009. Responding to challenges and finding solutions is not confined to mathematics but arises in all areas of learning, says Sheila Ebbutt.

  19. How to Strengthen Your Preschooler's Problem-Solving Skills

    When teaching your preschool-aged child how to problem solve, consider these four steps that are used in early-childhood classrooms : Identify the problem. Brainstorm solutions to the problem. Choose and implement one of the solutions. Evaluate how that solution resolved the problem. Following this four-step guideline can help the adults in a ...

  20. Problem Solving with Others

    Teach, Model, Support. Young children are still learning how to socialize, collaborate, and negotiate with others. With our support, children can learn these valuable skills and work together to find solutions as challenges arise. Learn key strategies you can use to teach social problem solving in advance and support it in the moment.

  21. Problem Solving in the Early Years

    Storybooks and beyond: Teaching problem solving skills in early childhood classrooms. Young Exceptional Children, 19(3), 18-31. Crossref. Google Scholar. Forgan J. W. (2002). ... (2006). Developing a general outcome measure of growth in the cognitive abilities of children 1 to 4 years old: The early problem-solving indicator. School ...

  22. Research on early childhood mathematics teaching and learning

    Early childhood mathematics education is a rich field of study and practice that includes the provision of stimulating activities and learning environments, organized and orchestrated by teachers, care-takers and other professionals with the aim of offering young children experiences that extend their knowledge and development of mathematical co...

  23. Exploring Problem-Solving in Early Years & KS1 Mathematics

    This webinar will provide headteachers, mathematics leads, teachers and teaching assistants with practical guidance and methods they can use to nurture and develop pupils' problem-solving skills in early years and KS1 mathematics. Book Now (£60.00 + VAT) Unlock All Content With Membership. Description.

  24. 10 Critical Things Parents Should Teach Their Kids As Early As ...

    From their earliest years, it is crucial to impart valuable life lessons that will lay a strong foundation for their personal and interpersonal growth. By teaching important skills and instilling ...

  25. Phonics Worlds Pune

    22 likes, 0 comments - phonicsworldspune on October 26, 2023: "Learning the abacus in early years can offer several benefits for kids: Mathematical Foundat..."