“Saaliha, come with me to the light table,” Evelyn whispers. “I have to show you something!”

Hand in hand, the two preschoolers quietly make their way over to our light table. This darkened corner of our classroom never fails to mesmerize the children with its soft glow and luminous colors.

As the days grow shorter and darker—and the hectic holiday season approaches—it’s the perfect time to engage children in calming investigative play with light and color.

Before we gather around the light table, I dim the lights in the classroom and put on some soft music to create a soothing and tranquil setting for the children, who are often overscheduled, tired and anxious during these busy December days.

“Look!” says Evelyn. “I took a play silk from our dress-up bin and put it on the light table!”

Evelyn moves over to make room for Saaliha at the light table and the two friends immerse themselves in STEAM collaboration, problem-solving and investigation. The girls are completely absorbed in their play—and the learning is enhanced by the presence of a friend and collaborator.

“That’s cool!” says Saaliha. “It makes everything look a little different, but you can still see all of the different colors!”  

The light table allows for open-ended play, where children can experiment and create without strict guidelines. This type of play fosters the development of creativity and problem-solving skills as the children follow their curiosity, devise their own experiments and draw their own conclusions. This child-led play also fosters an investigative mindset, which can lead to hours of exploration and discovery.

“Try this!” Evelyn suggests as she shows Saaliha how to duck under the silk to compare the views. 

The girls experiment with different color combinations and share their theories and discoveries. The light table always seems to spark curiosity and encourages children to ask questions and seek answers.

As more children join the investigative play, they expand their knowledge base by collecting data and adding probability to their investigative skills.

This is a shared space that encourages collaborative investigations. Collaboration fosters communication skills, teamwork and the ability to share ideas with peers.

Children work together to create patterns, build structures and explore different materials—a process that helps foster the development verbal and social skills.

The hands-on nature of these activities promotes a deeper understanding of mathematical principles through play.

Children can investigate fundamental mathematical concepts such as counting, sorting, patterns and shapes on the light table. 

These long play periods extend the learning as the group explores spatial relationships, patterns and sequencing, laying a foundation for more advanced mathematical thinking.

Play at the light table is naturally enjoyable for young children. The combination of vibrant colors, interactive materials and the freedom to explore creates a positive and joyful learning experience that can contribute to a lifelong love of learning. 

Light tables allow children to learn at their own pace, which makes the play developmentally appropriate for every early learner. The children build on their own knowledge and share their observations with others.

When children are making observations and discoveries, they are forming and testing hypotheses. These self-directed learning experiences empower them to continue to explore and investigate beyond the classroom.

So turn on that light table and watch the magic of play and discovery brighten the day! 

“Oh, I like your mosaic, Avery!” says Claire, who has wandered over to look at the mosaic that Avery has just created with sidewalk chalk and tape. “Yours only had triangles. We did squares and triangles and those long skinny squares.”

“Oh, you mean rectangles! I want to see it!” Avery exclaims. He jumps up to compare their creations.

Our days have been full of busy children drawing shapes and creating colorful chalk mosaics on the sidewalk. This activity offers many opportunities to work on shape recognition while extending the learning to the outdoor classroom.

Start by creating a shape on the sidewalk or a flat surface with masking tape. Divide the inside area into smaller shapes. If this is your first attempt at introducing chalk mosaics to your students, I would suggest beginning with a few small areas that measure about two feet by three feet, with smaller shapes inside.

Why start out small? The children can see results faster—and smaller is better for our youngest students, who haven’t yet developed the hand and wrist strength to color in larger shapes. On a more practical note, I’ve discovered that smaller shapes are better when the children are using smaller pieces of chalk.

You can always go bigger as the children get the hang of chalk mosaics. If you have an endless supply of wasabi tape, this easy-to-tear tape enables them to create their own shapes inside the larger shape. 

Leaving a basket of chalk nearby will invite the children to start coloring in the shapes. Once the children have completed the mosaic, simply remove the tape and admire the masterpiece! 

As your students learn to identify shapes, they can use spatial orientation vocabulary to describe the relative positions of the shapes. Preschoolers should understand and be able to use positional words such as above, below, beside, in front of, behind, next to, between, on, over, under and inside.

Shapes are the foundation of geometry. Geometry involves shape, size, position, direction and movement.

In early education, geometric skills include identifying and comparing shapes, differentiating between shapes and creating shapes.

Children need hands-on investigation to understand more than just naming or classifying shapes. Our chalk mosaics introduce children to simple shapes—as well as more advanced concepts such as symmetry, angles and fractions.

“My chalk is shrinking really fast!” giggles Rowan.

Oh, how I love shrinking chalk! Yes, we are definitely collecting data, making observations and noticing cause and effect.

But there’s more happening here than meets the eye. We know that the transition to smaller writing utensils helps promote the development of better gripping skills. As the children continue to draw and their pieces of sidewalk chalk get shorter and smaller, they are effectively transitioning to smaller writing tools and increasing their grip strength.

We try not to rush writing in our young learners. But when it happens spontaneously, we try to promote the use of smaller pieces of chalk, crayons or pencils to help them develop age-appropriate gripping skills.

These are all bonuses for kindergarten readiness—above and beyond the early math learning standards. This is the foundation that we talk about when we play our way into academic life. These small steps will enable our children to succeed when it’s time to sit at a desk. 

I have a few insights into the hidden benefits of chalk play—insights that can be shared with parents who may question the value of outdoor play and its role in advancing their children’s kindergarten readiness. Kindergarten, sadly,  involves a lot of sitting time. Children need strength throughout their bodies—including strong core muscles to sit all day. When children get down on their hands and knees and support their upper-body weight with their arms and hands, this strengthens their core muscles, as well as their shoulder muscles, which are so important for fine motor dexterity.

There’s a lot of math built into our chalk play. Follow the lead of your students, connect the curriculum to the play and you’ll meet your learning standards every day!

Looking for more ways to play with shapes? Extend the learning with these Early Math Counts shape lesson plans!

“When we drive to school in the morning, the sunflowers are facing one way and when we drive home after school they are facing the other way. That’s because they always want to see where I am going!” brags Melania to the other children on the bus.

“That’s not true,” grumbles Roberta, who is clearly not a sunny morning person.

“Yes, it really is true! Melania insists. “Ask my dad!”

I planned this morning field trip to a local sunflower farm to set the stage for some hands-on STEM learning. But it’s going to be a long Thursday if the kids are already arguing about the science behind the sunflowers we are about to see.

Hoping to lighten the mood on the bus and soothe the “hangry” Roberta, I reach into my bag and pull out some Sun Butter Energy Bars.

“Actually, what Melania is saying is partly true,” I explain as I hand out the energy bars. “As a sunflower grows, it turns its face to follow the sun from sunrise to sunset. So the sunflowers do face in one direction when Melania sees them in the morning and another direction when she sees them in the afternoon.”

By the time we arrive at the sunflower farm, the energy bars have worked their magic. Roberta’s morning grumpiness has dissipated, everyone seems perkier, and the group is staring at the giant flowers in amazement.

“Look at how tall they are!” gasps Lauren. “They are even taller than the grownups!”

“Can I touch one?” asks Lauren. She reaches up and touches the center of the sunflower. “It’s bumpy,” she observes. “Wait, inside the middle, are those all little tiny sunflowers? Look! There are a million little tiny flowers inside the big flower head!”

Maybe not a million, but this is a great opportunity to introduce concepts such as quantity and estimating. In fact, one of the best places to strengthen math skills is in the garden!

Whether you bring flowers into your classroom, plant a school garden or take a field trip to a sunflower farm or a pumpkin patch, you can extend the learning by creating hands-on opportunities for children to practice their early math skills. When children observe, measure, compare and analyze their surroundings, it helps them make sense of their world.

“Look how big this one is!” says Jason, staring up at an enormous sunflower in awe. 

I pull out a measuring tape so that we can measure how tall it is. We discuss how to measure an object. This leads to a conversation about concepts such as diameter and circumference.  Of course, these concepts are too advanced for this group, but I like to “plant the seeds” for later vocabulary development.

As we wander through the sunflower farm, I prompt the children with conversation starters such as:

“I wonder how many seeds they planted.” 

“I wonder how tall the sunflowers get.”

My goal? To inspire the children to find the math hidden in this field of sunflowers and start asking questions of their own.

“I wonder how many times people get stung by all those bees hanging around the sunflowers?” muses Roberta.

“There are a lot of bees!” responds Melania, ever the Pollyanna to Roberta’s pessimist. “But they aren’t bothering us. They are so busy eating nectar that they don’t even know we are here.”

“Look, this one has three bees on it!” observes Jason. “Look, Roberta! Let’s see if we can find more!” 

When children are learning to count, they love counting anything, even bees! By teaching math in the garden, you can show children how we use math in our daily lives.

Soon the children are comparing the sunflowers in the field, using math vocabulary words such as big, bigger and biggest, small, smaller and smallest, and tallest and widest.

When you return to the classroom, you can build on this lesson by encouraging the children to arrange flowers, fruits or vegetables in order from smallest to biggest or biggest to smallest.

Our morning at the farm has inspired a morning of math-filled conversations. From the shapes that make up the sunflower, to counting bees to measuring stalks, math concepts come to life when we take the time to look for math in our everyday encounters.

Ready to find more math in the garden? Check out these Early Math Counts lesson plans: The Tiny Seed and Flower Fun.

“I-am-a-robot!  I-can-do-anything!” squeaks Terrell in his best four-year-old robot voice.

“Oh, I like that you used that octagon for your robot’s head,” says Michaela. “I am going to try that!” 

We are deep into robot construction this month and robots are popping up all over our play spaces. We are constructing robots from clay. We have block robots. We have MagnaTile robots and button robots. What a great opportunity to work on shapes and spatial reasoning! 

When children play with shapes, they are building rudimentary skills that lay the foundation for later math learning, as well as reading and writing. Shape recognition and identification can help children understand signs and symbols. Children begin to notice shapes before they have the language to name those shapes. In the toddler and preschool years, children learn to name their first shapes: circles, squares, triangles and rectangles.

Shapes are the foundation of geometry. Children need hands-on investigation to understand more than just naming or classifying shapes. Our robot play acquaints children with simple shapes—as well as more advanced concepts such as symmetry, angles and fractions—as they engage in activities such as measuring, counting or investigating 2D and 3D shapes.

Geometry involves shape, size, position, direction and movement. In early education, geometric skills include identifying and comparing shapes, differentiating between shapes and creating shapes.

During our robot-building bonanza, the children are combining shapes in their constructive play. I watch as they learn that they can combine two squares to make a rectangle. They begin to see what happens when they turn a shape upside down. It is still the same shape even if it looks different. 

Research suggests that preschoolers’ early mathematics learning—including spatial-thinking skills—is related to later success in both reading and math. When children hear us use spatial terms to describe the size, shape and location of objects—and then adopt those words themselves—they perform better in activities requiring spatial skills.

Playing with blocks and puzzles and using spatial words such as above, below, across, on top of, inside and outside enables children to talk about where things are located. This strengthens their understanding of these concepts as they use the vocabulary words repeatedly throughout their play.

Geometric shapes are a kindergarten common core standard, and when children actually play with shapes, the learning becomes deeper, more intentional and more relevant. When children manipulate 3D shapes during hands-on play, they build a deeper understanding of these shapes.

Research has also shown that young children’s spatial skills—rather than their numerical abilities—predict their overall mathematics achievement. The key skill is visualizing what the shapes will look like when they are combined or rotated (Young et al., 2018). A focus on shapes and spaces may provide a more accessible route to math for some children, rather than focusing on numbers alone.

Spatial reasoning develops when children learn how to recognize relationships between 2D shapes and 3D shapes. How is a circle like a ball? How is a square like a box? As children discover that they can rotate, flip and rearrange shapes in different ways to change their possible shape and direction, they become increasingly aware of 2D shapes.

There is a lot of math built into our robot play. Follow the lead of your students, connect the curriculum to the play and you’ll meet your learning standards every day! 

Looking for more ways to play with shapes? Extend the learning with these Early Math Counts shape lesson plans! 

As the days grow shorter and the slanting rays of sun that create our rainbows are replaced by clouds, we shift our energy to other forms of investigative play with light and color.

“Saaliha, come play with me at the light table!” Nora calls out.

Saaliha joins her friend and the STEM investigations into light, color and reflection continue.

“Watch what happens when I put all of the reds together,” instructs Nora. “But look! It’s not really red. It’s pink! Ta-da!”

Saaliha is immediately drawn into this color exploration. I watch as Nora moves over to make room for Saaliha at the light table and the two friends immerse themselves in STEM collaboration, problem-solving and investigation.  

“It is pink! Can I have the red one?” Saaliha asks. Nora passes a transparent half-sphere her way.

The girls experiment with different color combinations and share their theories and discoveries.

We love our light table because it never disappoints, stimulating long periods of intense play as the children lay translucent objects one over the other.

Light-table play can be a calming, absorbing experience for a child, and the learning is often enhanced by the presence of a friend and collaborator.

These explorations of color and light also offer opportunities to assess the children’s predictive abilities. As the children expand their knowledge base through trial and error, they collect “data” and add “probability” to their investigative skills.

Everything and anything translucent can be used in light and color play. We add a variety of colored translucent tiles to the light table, cut cellophane sheets into shapes to create mosaics and layer translucent paddles to create new and sometimes unexpected colors.

We add bingo chips and clear and colored gemstones to the mix to encourage counting and sorting by attributes.

Translucent blocks and Magnatiles inspire the children to create 3-D structures and see the interplay of light, color and reflection in three dimensions.

I keep baskets of loose parts near the light table so that the children can use them for unstructured, self-guided play.

I also stock up on non-traditional items such as cocktail stirrers, colorful shot glasses and reusable plastic ice cubes at the dollar store. While these objects may look more like happy-hour supplies than learning tools, they represent a treasure trove of loose parts to children. Sea glass is also a great idea. In short, if it’s translucent, add it to your light-table area!

I rarely tell children how or where to play with toys. Occasionally, children will bring wooden blocks or other non-transparent toys over to the light table area. Out of respect for their creative process, I’ll allow it—unless, of course, the objects are heavy enough to damage the light table. These non-translucent objects are an important part of the children’s investigations. All objects look different when lit from above and below, and when viewed from different angles. This open-ended approach to play gives the children more latitude to create and investigate with color and light.

A few of my students are developmentally ready to start learning the alphabet. Some recognize letters, while others just perceive the letters as shapes. I make sure that the letters are accessible to my early learners at all stages of brain development and leave it to the children to make up their own rules for letter play.

Sometimes we add a play silk to the light table, which changes the children’s perspective and introduces new ways to play with light, color and reflection.

The light table supports our students as they make observations, think scientifically and collaborate with their friends while investigating new ideas and theories.

I love this learning tool because it’s always developmentally appropriate. The children build on their own knowledge and share their observations with others.

When children make their own observations and discoveries, they are forming and testing hypotheses. These moments of learning empower them to continue their exploration and investigation outside of the classroom.

This self-guided exploration paves the way for inquiry-based learning. So turn on that light table, trigger some curiosity and watch the magic of play and discovery brighten up your day!

“Evie, come look! I’m a superhero! I have superpowers!” calls Jamie from the foyer.

Curiosity piqued, Evie leaves her blocks behind to see what her best friend is up to now.

“Rainbows!!!” Evie shrieks as she spies the colorful light pattern on Jamie’s wrist.

Everyone within earshot dashes over to see the rainbows. And, just like that, our morning activities morph into a joyous exploration of light and color.

Squeals are the soundtrack for this sudden spasm of joy as the children dance around the room “catching” rainbows.

The rainbows that have inspired this impromptu STEM investigation are coming from the leaded-glass windows on our old schoolhouse.

During the winter and early spring, the sun hits these windows at just the right angle and we find these refracted-light rainbows on our walls, the floor—and even on the faces of napping children.

“I know the colors of the rainbow!” Noah sings. “R is for Red, O is for Orange, Y is for Yellow…” 

A chorus of little voices joins in, along with requests for our favorite “ROY G. BIV” song from the children’s CD, Here Comes Science (see image below).

The song is used as a mnemonic aid to help children remember the colors of the visible light spectrum in order of increasing frequency: Red, Orange, Yellow, Green, Blue, Indigo and Violet.

Color recognition marks an important developmental milestone.

Color identification helps children strengthen the cognitive link between visual clues and words.

Noah is singing the ROY G. BIV song while pointing to each color. As I watch, I make a mental note to check off color recognition, vocabulary and sequential ordering on Noah’s upcoming learning assessment.

I attempt to explain that the rainbows in our classroom are created when the sunlight gets “split up” as it passes through a cut-glass window that bends the light.

“Red tends to bend the least, so it appears on the top of the rainbow, while violet bends the most and ends up on the bottom,” I state.

My jabbering is met with silence. The children are deep into their own investigations.

“The librarian told us that rainbows are actually circles, but they look like arches when we look at them from the ground,” says Owen.

Heads pop up. Owen’s comment is met with quizzical expressions as the children try to process this information.

“If we dig down into the ground would we see the rest of the rainbow?” Roberto asks. 

“I don’t know,” shrugs Owen, glancing around at the rainbows in the room.

“What’s an arch?” asks Thali.

“You know, that part of the circle that looks like this,” says Jamie as he creates a half-circle with his hands. “It’s like you cut a circle in half!”

Thali nods and the focus of the group returns to the rainbows in the room.

This interaction prompts us to bring out our prisms and inject a bit of STEM into our hands-on play. Throughout the day, we experiment with other materials and sources of light.

First, we add Magnatiles to the windows in our block area (above).

Then we grab our liquid tiles (below) and place them in the window frame. We love these tiles and play with them often, but this is the first time we’ve tried to place them in the window. The colorful liquid in the tile is reacting to the pressure of Sally’s fingers, stimulating her sensory, perceptual and spatial pathways.

I offer a large liquid floor tile to our younger learners. Some of the older children immediately join in the exploration, adding enough weight and pressure to move the liquid and stimulate the senses of our younger friends.

If you don’t have cut-glass windows, a simple window film can bring about the same results. We added this film to the window below, and we are greeted with rainbows whenever the sun shines!

When these spontaneous moments of learning land in our classroom, my goal is not for the children to completely comprehend or master a topic.

My goal is to learn with them, to pique their curiosity with investigative opportunities and to allow them to engage in scientific inquiry while playing with light.

The act of playing with light, reflection and color invariably evokes a sense of wonder.

So seize the moment for some impromptu STEM play when a rainbow spontaneously appears—and expand the options for color and light exploration with a few new prisms and props!

Our moment of silent concentration and focus is interrupted by Parker ecstatically showing off her geoboard.

“You made a house?” asks Linnea, looking a little wide-eyed and confused. “How did you do that?”

“I just added shapes and it worked!” Parker answers, equally amazed by her own creation.

“I want to try that!” shouts Rowen.

“Me too!” echoes a chorus of four-year-old voices. “Show us how you did that!”

Geometry has entered our world today—and what better way to learn about early math and science concepts than through play?

I have come to believe that geoboards are one of the ultimate learning tools for peer mentoring. I watch as the four-year-olds follow Parker’s example and create their own versions of her rubber-band house.

I am a huge fan of these little powerhouses known as geoboards. Hands-on activities with these simple learning tools get children’s brain synapses firing like crazy and stimulate the development of new neural connections.

The boards, with their colorful rubber bands and infinite possibilities, also make math and engineering fun!

Our geoboard play tends to occur in cycles. Today, the geoboards have resurfaced after long hiatus.

Because the children haven’t used the geoboards in a while, I notice how much their brains have developed since the last time the boards were in play. Seeing these leaps of brain development is one of the great joys of teaching.

Geoboards are always developmentally appropriate in the hands of the creator. Some children simply work on stretching the rubber bands onto the nails. My “artsy” early learners—who are happy designing anything and everything—can play with these boards for hours. And there’s a child in every class who insists on attaching every single rubber band in the bag to the geoboard, persisting long after the other children have moved on to new activities.

Geoboards enable even young children—and those who may have difficulty drawing shapes—to construct and investigate the properties of early geometry without a pencil in their hands.

I see geoboards as a chance to level the playing field for those who struggle with grasp, fine-motor or visual-motor skills.

Children begin to notice shapes before they have the language to name those shapes. Geoboard play acquaints children with simple shapes—as well as more advanced concepts such as symmetry, angles and fractions—as they engage in activities such as measuring, counting or investigating 2D shapes like Parker’s rubber-band house.

Look at those little fingers and hands going to work! With just one geoboard and a bagful of rubber bands, children can create and learn about shapes while developing their hand muscles, fine-motor skills, spatial skills and math skills. This is why geoboards have been a part of our classroom curriculum for more than 30 years.

Children can use their rubber bands to create squares, rectangles, triangles and other “sided” shapes. They can also explore number concepts as they try to stretch a single rubber band around a certain number of pegs. They may try to stretch it around three or four pegs—or maybe even all of the pegs. This early math exploration evolves quite naturally as the children engage in geoboard play with their friends. 

When I introduce geoboards to new students, I leave the lesson plans and benchmark checklists for later and let the children simply play with their boards. I want them to engage in geoboard play at their own level of development.

It’s important to give the children ample time to engage in this process. It can’t be rushed. For my young learners who love to make shapes, letters and designs, a longer play period gives them time to get their creative juices flowing. As their brain development continues, you will see their shapes and designs become more intentional.

Young children develop ideas and concepts about science, technology, engineering, art and mathematics (STEAM) naturally. They think about size, shape, quantity, order and speed throughout the day as they play and explore. As teachers of young children, we need to tap into their natural curiosity with intentional STEAM learning opportunities such as geoboard play.

Intentionality is acting with knowledge and purpose. It is the opposite of chance because it is planned and thoughtful. In order to become intentional about math teaching, we need to think about math the way we think about literacy.

By making shapes on their geoboards, the children are actually developing important pre-reading and pre-writing skills too.

Here’s how it works: When Linnea sees a shape on the geoboard and names it, she is preparing herself to identify letters and numbers and then naming and eventually writing them.

Simply by placing a basket full of geoboards near a table, we can encourage children to experiment with shapes, sizes and direction through hands-on play.

We can call this math, science, engineering, art or literacy because it’s laying the groundwork for the STEAM disciplines, as well as language development.

But in our hearts—as early childhood educators—we simply call it play.

“Look!” squeals three-year-old Eleanor.  “I can pick up these two balls! It’s magic!”

Have you ever seen young children playing with magnets? The “magical” properties of magnets never fail to captivate early learners and spark a play buzz!

Children learn by investigating, observing and figuring out how things work. Magnets fuel that curiosity in a way that is simple and accessible.

As they explore the properties of magnets through play, children develop a deeper understanding of scientific principles by asking questions such as “why” magnets stick together and “how” magnets work.

Magnetic play helps lay the foundation for further investigations as we guide the children through activities such as developing hypotheses and theories, solving problems and making predictions. By observing and studying cause and effect, our young STEM explorers can begin to develop a basic understanding of concepts such as magnetic attraction, magnet strength and magnetic forces and fields.

Playing with magnets is a great way to introduce STEM into a child’s life. If you need to record observations, this is a great time to take a seat and watch as children incorporate predictions and conclusions into the learning experience.

To set the stage for magnetic exploration, I put out a wooden tray filled with magnetic wands and magnets in a variety of shapes and sizes. Then I give each of the children an aluminum tray to define their play space and keep the magnetic balls from rolling off of the table onto the floor.

When children add magnets or remove them from the tray, they are learning about math concepts such as more, less, off and on. They’re also learning about patterns, shapes and sizes.

I also fill simple sensory bins with colored rice or coffee beans. Then I add magnetic and non-magnetic objects, as well as a magnetic wand for finding the “treasures.” I set two baskets nearby to encourage the children to sort their objects.

“Is this magnetic?” asks one child. “This should work,” says another. “It’s silver!”

Making a prediction means focusing on what we think will happen next based on our prior knowledge. It’s considered a guess if we have no prior knowledge. We can help children develop their prediction skills when we are playing with magnets, reading a story or finding our way home on a walk.

When the children at our early learning center play with magnetic wands and balls, they love to “catch” the balls on the wand and count how many they have. Sometimes I will see them intentionally create patterns.

Playing with magnets is a powerful math and science activity in early childhood classrooms because it fosters conversation and exploration and provides a fun and engaging incentive for children to make predictions and observe outcomes.

If you can, give the children a long period of time to investigate the magic of magnets and work through their theories. This extended time to conduct STEM investigations and learn through focused play is a gift that they may not be given in their future academic lives.

It will amaze you when you see the amount of time that children will spend exploring the magnets on their tray. It’s a calm, quiet and very, very focused activity that slows down even our most frenetic friends.

As we continue to play, we engage in a discussion about the forces that pull magnets together. We keep it pretty basic. This young group hasn’t shown any interest yet in the whys and the hows of magnetic forces and fields. They are too enchanted by the magic of it all. I have been down this trail before. When the brain is ready, the questions will be asked and we will have the resources available to answer their questions and push the experiments and investigations a wee bit further out of their comfort zone. There will be many more experiments for extended learning. But, for now, exploring the magic of magnetism suits us all just fine! 

A few words of caution. Magnets are dangerous if ingested. We hope that our students no longer put everything in their mouths, but we can’t count on it. You know your students better than anyone. It is best to err on the side of caution and use large magnets that cannot possibly fit into a child’s mouth if you are at all concerned. It will make the day of magnetic play more enjoyable for YOU if you don’t have to worry.

Stay safe and take care!

After months of sequestering and social distancing to stop the spread of COVID-19, we could all use some fresh winter air! Nature is just what the doctor ordered to stimulate our senses while we meet our early learning standards.

The winter months offer an abundance of STEM learning opportunities, so don’t let the falling temperatures and snow chase you inside. The changing seasons lead to so many discoveries that incorporate STEM language and learning. Let’s take a quick look at just a few of the STEM learning adventures that we can provide for our early learners as we explore the winter landscape.

SNOW MOLDS

When the forecast predicts the first snow of the season, be sure to grab the toys out of the sandbox before they freeze in the sand. Then repurpose your sand molds as snow molds. It’s a great way to introduce shape and dimension into winter play.

This cold-weather activity introduces early learners to engineering design and the scientific practice of modeling as they work through their ideas in this new medium. By actively investigating, exploring and communicating with their friends, our young snow sculptors are laying the foundation for a future understanding of core scientific concepts.

When children have access to simple sandbox tools, they can explore and reimagine activities that work with sand, but may or may not work with wet or powdery snow. This leads to more investigation and more opportunities for learning. Muffin and cake pans of all shapes and sizes will also work—and open doors to endless hours of creative outdoor play. 

ICE AND ICICLES

There’s a lot of science and math in those icicles! Every winter, I grab the longest icicle that I can find and let it melt into an empty glass. This enables the children to observe the melting process while we discuss the difference between indoor and outdoor temperatures. We can also discuss why our body temperature is warmer than the outdoor temperature and why we can see our breath in the cold winter air. When the icicle has completely melted, I point out the dirt and gunk that was frozen into this seemingly pristine piece of ice. But that won’t deter our experiential learners from sucking on “nature’s popsicles.” Children learn through their senses—and I gave up the battle of trying to stop them from sucking on icicles and eating snow years ago. It’s all part of the magic of winter STEM learning.

IGLOOS

Building an igloo is easy—and there are so many learning opportunities in engineering and physics that come into play. We use large plastic bins to mold the snow into big blocks, and the igloo-building process proceeds more quickly than you might imagine.

If you’re lucky enough to get packable snow early in the season, there is a good chance that your igloo could last for a month or more. One word of caution: This lovely source of wind protection also takes a while to melt, so build it in a location where it won’t interfere with other activities. Because igloos become softer in the afternoon sun, we often redesign our igloo during the day, adding colors and water before leaving it to refreeze overnight. An igloo is well worth the investment of time and energy.

HIKING

Take a hike! Even in familiar places like your neighborhood or a local schoolyard, life looks different during the winter months. When we head out for these winter walking adventures, I introduce new vocabulary words such as “hike” or “adventure” or “excursion.”

Research shows that vocabulary building at an early age fosters future success in reading and narrows the achievement gap. As you hike with your early learners, your efforts to introduce concepts such as patterns, reflections, black ice, hibernation and wind-chill factors will lead to later learning opportunities back in the classroom.

  

SLEDDING

Oh boy! What a bonanza of science vocabulary we have here, with “speed” and “force” and “distance“! For younger children, we introduce simple vocabulary words such as “up” and “down” the hill.  Who went the “farthest“? Who wiped out the “fastest“?  We gather and analyze data as they try new routes, techniques and combinations of sled buddies. We don’t always have access to real hills—and there have been years when my class just couldn’t handle a walk to the park and sledding!  But don’t rule out that large pile of snow that the plow has pushed up at the end of the school parking lot.  It may be man-made and it may be small, but it’s a hill nonetheless! Kids just love taking small risks such as climbing up and sliding down. Last winter, I watched a three-year-old and a four-year-old spend 20 minutes trying to stay upright while sliding on their boots down an 18-inch “hill.” It doesn’t take much of an incline to open doors to STEM learning!

ANIMAL-TRACK INVESTIGATIONS

We often discover animal tracks in the snow during our outdoor investigations. We occasionally find paw prints from a raccoon or hoof prints from a deer, but most of the tracks that we find are made by neighborhood cats and dogs, as well as squirrels and birds. This tracking activity never gets old. We can try to follow their routes while making observations and forming theories. Curiosity, persistence, questioning and problem-solving are the traits of a true scientist. These real-life adventures that put science in context represent age-appropriate learning at its finest.

SNOW SCULPTURES

I’d love to tell you that we were the designers of the impressive Snow Dino below, but the truth is that we found this expressive fellow while sledding at the neighborhood park. We have some very creative college students in our neighborhood and we often observe their winter snow sculptures to get our own creative juices flowing and learn new sculpting techniques. The smiles on the faces of the children below show that they didn’t need to build the Snow Dino to enjoy the end result! If you missed our own STEM Snowman adventures earlier in the month, you can find the blog post here.

After the cold-weather fun, finish up with a comforting cup of hot cocoa, apple cider or mint tea. When the weather is warm enough to stay outside for long periods, a hearty cup of soup after you head indoors will chase away the winter chill and refuel your STEM explorers.

Thank you for sharing a year of STEM learning adventures with me and stay tuned for more in 2021!

“Look! The snow packs!  Let’s make a snowman!”

Today’s sunshine and rising temperatures have transformed yesterday’s powdery snow into packable fun—ushering in an afternoon of playful math and science learning.

These are the times when I love to pull out my camera to document the many foundation-building moments that find their way into our play. This documentation allows us to reflect on the learning, conversations and collaborations that take place—and the theories that the children develop—as they explore and investigate their environment.

So grab a mug of hot cider and join us as we unpack all of the early learning opportunities that can be checked off of your list of assessment standards during a snowy afternoon of outdoor play.

“We need three balls!” yells Hudson. “One for his head, one for the middle and one for the bottom!” Hudson has stepped up to serve as the lead architect during this day of snowman construction.

 “We need three sizes,” Jameson pipes in. “Big, bigger and even bigger!”

  “Yes, and the biggest is at the bottom,” adds Noah.

“You start out like this,” Noah explains as she packs together a small pile of snow. ”You push it and roll it and it gets bigger and bigger. Then you have to pack it down. But not too hard. If you pack too hard, it falls apart.”

As I listen in, I seize various opportunities to introduce some STEM vocabulary into our play. We discuss cause and effect, friction and experiments. I don’t expect these words to start flowing off of the children’s lips any time soon, but I never miss an opportunity to plant the seeds of knowledge in their developing brains.

“Mine looks like a square,” Jameson complains to no one in particular.

“If you rub it here just a little and chop this side a little bit, you will make a circle,” advises Avery, who is a wee bit older and more experienced in the intricacies of snowman construction.

I watch as the children form the snow into balls of different shapes and sizes. I hear vocabulary words such as “bigger,” “taller” and “heavier” as the older children compare the different snowball sizes and help me stack them one on top of the other to form snow people.  

“We need two eyes and a carrot nose and buttons for the mouth,” the children shout. “We need a hat to put on top and two branches for his arms! He needs a hat and a scarf!”

For years, the needs of my little “snow sculptors” left me scrambling for the items needed to complete their snow people. After three decades of coming up short, I discovered this snowman decorating kit on Amazon.

What a game changer! This affordable kit provides ample opportunities for STEM (and STEAM) learning. Whenever I pull this kit out, the excitement increases and the design process becomes more focused and deliberate. We have patterns and sequence and spatial reasoning. We have order and math vocabulary and collaboration. These are the moments that lead to teamwork, which is such a gift in any learning endeavor. When children work together on a project, it fosters the development of confidence and camaraderie—and culminates in a sense of accomplishment for all.

I keep my snowman kit in a plastic bin so that I know where all of the pieces are and keep the bin handy during the winter months. Every time I pull the kit out and the children scream with delight, I feel like a rock star! If you want to simplify your teaching and incorporate more STEM learning opportunities into your snow days, do yourself a favor and get a snowman kit.

The winter months offer endless opportunities to introduce children to the science behind the season as you explore and discuss environmental changes, physical properties, weather and temperature. You can pack a lot of STEM curriculum and vocabulary into your day by simply allowing your students to spend some time in the elements.

If the thought of getting all of your young snow explorers dressed and out the door feels daunting, check out our blog post, Incorporating Math into Your Cold-Weather Routines. You’ll learn how to set up separate “stations” where the children can don their own snow pants, coats, boots, hats, scarves and mittens. It’s a great system that teaches children about sequencing while encouraging them to become more independent as they gear up for their winter adventures.

It’s going to be a long winter, so bundle up and get some fresh air.  It’s good for the body, the brain and the spirit.

Stay safe my friends!