Today is one of those magical winter mornings when snow blankets the ground and clings to the trees around our center.  The sun is shining and the world looks so sparkly and irresistible that we head outside in spite of the freezing temperatures.

“Hey! Who has the smiling boot?” Jacoby calls out to the group. He scans the play space, which looks like a snowy white canvas dotted with boot prints.

“Do you have the smiling boot?” he asks Maria.  

Maria looks confused as she glances down at her boots. “No, my boots are pink.” 

“No, no…on the bottom!” Jacob points to her boots. “Does your boot have a smiling face on the bottom?” 

Even I am confused by Jacoby’s question—until he points to the clue in the snow. 

“Look!” he declares. “Somebody has a smiley face on the bottom of their boot.”

Ah-hah! Indeed, we do have a smiley face boot print staring up at us from the snow-covered ground. Well, this will warm us all up!  Let the STEM investigation begin!

After a fresh snowfall, it’s so much fun to find and follow animal tracks. But we’ve never really paid attention to the patterns on the soles of our boots until now.

One by one, Maria and Jacoby begin to check the bottom of each friend’s boot. This simple moment of exploring patterns leads us to measurement, reasoning and comparing attributes.

Young children instinctively seem to notice attributes. It may be the shape, size, color, length or some other characteristics of an object, such as today’s smiling boot face.

Children develop their understanding of matching and patterns through experience. Because it’s difficult to consider a lot of attributes at once, children often begin creating sets by finding exact matches.

When children create pairs of boots or find an exact match to the smiling boot face, they are creating sets of items that are exactly alike. Maria and Jacoby are using rudimentary math, science and engineering skills as they observe and ask questions—all while solving the smiling boot print mystery!

Suddenly, everyone is stomping their boots and comparing and analyzing the shapes and patterns that their boots are leaving in the snow.

“I have zigzags!” announces Liam.

Sure enough, as we all run over to look at Liam’s boot print in the snow, we see row after row of zigzags.

“They look like mountains!” laughs Rokia. “That’s so cool!”

 “I have rectangles!” announces Rachel. “If I turn around, it looks like a house with a roof. Look!  See, at the bottom of my boot print?”  

Our focus is now very intentional and the mood has shifted from playful curiosity to deep observation and concentration. 

This is what child-led learning looks like. For those of you who believe that “child-led learning” can only lead to chaos, I urge you to put on your winter wear, head outside and see how effective and wondrous it can truly be.

“I have diamonds!” shouts Julio, “Oh and triangles at the top and bottom. Wow! Look at my boot print, it has really cool patterns.”

We are working on spatial reasoning, direction and positional vocabulary. This is the deep learning that takes place when children have ample time to explore and investigate.

Every day, children learn something new.  Every day, they deepen their understanding of STEM principles and share their insights and theories with their fellow STEM explorers.

Time is the key to deep learning!

“I have snakes!”  Josie shouts.

“Snakes?” 

Everyone comes running to see the newly discovered boot-print pattern. And, yes indeed, Josie’s boot print really does look like snakes.

But Isaac sees it differently. “I think it looks like waves,” he counters. “You know, like when you throw a rock in the river and it makes those lines?”

Then five-year-old Maya reorients the group to the smiley-face boot prints that started the morning’s STEM investigation.

“Where did that smiley face boot come from?” she asks, putting an end to the snake-shape and wave-shape discussion.

“I don’t know!” retorts a frustrated Jacoby. “That’s what I am trying to figure out!” 

“No, I mean, where did the smiley face boot print start?” Maya clarifies, assuming the role of lead investigator. “Where did you find it? Did you follow it, like we followed the cat paw prints last winter?” 

Jacoby pauses and I can see the wheels turning as he considers Maya’s questions. This is a lightbulb moment when the children suddenly recall a forgotten game from winters past. We have plenty of wandering cats in our neighborhood. For years, we have engaged in follow-the-cat-print expeditions on snowy days, following the tracks and trying to figure out the exact route that the cat took and why. Today has ushered in a new season of snow—and now we are rediscovering the game all over again.

Five-year-old Maya has had a few more years of brain development and a few more years of winter play, so she has retained more memories of those snowy-day games than the younger children who started the smiling boot print investigation.

Suddenly we are tracking movement, direction and the changes in how the boot print is left. We don’t have paper and pencils to collect data outside today, but our friends are forming hypotheses and making deductions as they piece the clues together and abandon the ideas that don’t pan out.

Maya continues as the lead investigator. “Look at the size of this boot track. It’s much bigger than our boots. See? I think it’s an adult boot print. Look how far it is between the foot prints. It takes me three steps to their two steps.”

“Maybe it’s the mail carrier,” suggests Lois.  “She brought a package to the door yesterday.”

“It can’t be the mail carrier,” reasons Maya. “She doesn’t walk on this side of the center.”

“It must be a parent!” shouts Jacoby. “Who has a parent with a smiling boot?”

The question is met with dead silence. No one knows the answer.

Suddenly, Maya turns to me and asks, “Do you have a smiling boot? You are an adult.”

Much to my disappointment and the chagrin of my young friends, I am not the owner of the smiling boot. We are getting cold and our investigation has hit a dead end. We decide to go indoors and warm up with some hot cocoa and banana muffins.

At pickup time, the children check the boots of every parent for a smiling face, but no one has the matching boot. Many weeks later, we discover that the smiling boot belongs to a grandparent of one of the children at our center. By then the thrill of the hunt is over. But the learning has not been lost. A great morning of STEM investigation is tucked away safely in the developing brains of our early math explorers.

Ready to start your own Snowy Day STEM Investigation? Check out Show Me Your Shoe, an Early Math Counts lesson plan that can be adapted for your own boot-matching investigation!

Do you have collectors in your midst? Those young children who can turn a five-minute walk into a 15-minute treasure hunt? The children who fill their pockets with treasures and then load up your pockets with the overflow?  I love these kids. They can wreak havoc with our daily schedules, but they help us slow down, take a breath, smile and find beauty in unexpected places. They also make me smile when I remind myself that these impromptu, child-led collecting and sorting expeditions are worth their weight in gold as we work with young children to build a strong foundation for later math learning.

We collect lots of natural loose parts like acorns and buckeyes, feathers and rocks. But we also collect colored gems, bottle caps, keys and other odd items. This, my friends, is the rock-solid, hands-on play that lays the foundation for number sense.

At all ages, children classify intuitively to make sense of a world that seems largely out of their control. By the time infants are two weeks old, they can distinguish between objects that they suck on and those they do not. By the age of two, toddlers form sets of similar objects. In preschool, children begin to sort objects into categories according to a given attribute.

If it attracts their attention and they touch it, that’s the moment the child-led learning begins! So grab a bag, a basket or a bucket, take a walk and see what sparks the imagination of the children in your life. A good pocket comes in handy on these expeditions!

Along the way, observe the collecting habits of your budding mathematicians. What captures their attention? What treasures do they deem worthy of pocketing? Does one of the younger treasure hunters in your group need guidance or mentoring?

During your expeditions—and other daily outings—keep your eyes out for heart rocks. It’s a great opportunity to build some early math skills, whether you’re waiting for a table to open up at a restaurant or killing time before an appointment. Hidden in those landscape rocks, there is sure to be a heart rock!

Children will naturally begin to sort their collected treasures into piles or “sets.” Separating will come very naturally as children sort acorns into one pile and bottle caps into another. They may group by colors, shape, texture or weight. They may also organize their objects in a line by size or other attributes.

As they sort the objects that they collect, children are building their analytical thinking skills, which are the lifeblood of mathematics. This is a great opportunity to introduce vocabulary words such as more and less.  Young children have an inborn sense of more and less. They always know if someone has more than they do!  Children can learn number sense simply by playing with their collections!

If the grouping of sets leads to counting, this is another great opportunity for young children to build foundational math skills. Regardless of how high a preschooler can rote count, a child’s sense of what those numbers actually mean develops gradually. We call this “understanding number sense,” and it requires relating numbers to actual quantities.

There are three core counting principles:

Counting Sequence 
There is an ordered sequence of number names. Counting involves using the same sequence each time, starting with one. By using counting songs and moving each object as you give it a “name,” you can help children learn the counting sequence.

One-to-One Correspondence
One number from the counting sequence is assigned to each object in a collection. Instruct the children to put each object into a container or slide it across the table as it is counted.

Cardinality
The last number assigned to an object when counting a collection indicates the total quantity of objects in the collection. Ask: “How many?” If the children don’t know the answer to this question, count the objects together and note the last number that you counted as you push the objects all together into a group.

By turning counting into an enjoyable, hands-on activity, you are also introducing the children to mathematical concepts such as place value and addition.

Remember to take it slow and make it fun. Children develop at different rates and have different learning styles. They will master early math concepts in their own time and in their own way.

So let the children set the pace. Enjoy the cooler fall temperatures as you embark on your collecting expeditions—and see what collections land in your pockets!

Looking for some great activities to introduce sorting and counting to your early learners? Look no further than the Early Math Counts lessons page.

Here are a few of my favorites to help you get started:

• Cereal Sorting
• Laundry Sorting
• One Fish, Red Fish

“Who wants soup? I am making soup for lunch today!” Eleanor shouts to anyone willing to join her as she “cooks up” her concoction.

Eleanor is our concoction wizard. She can often be found adding loose parts to a large pot of water, mixing away while she muses about the ingredients she needs to add to her “recipes” for soup, magic potions and smelly perfumes.

“Aw, I don’t want soggy flowers in my soup!” Jose protests as he peers into the pot. “I like it better when you sprinkle them on top. Can you make the flowers dry again?”

Eleanor is a master at transforming dry flower petals into wet soup ingredients. But she hasn’t yet mastered the art of drying the wet petals with a swish of her stick.

“I can’t make them ‘not soggy’ anymore,” she admits. “But I can add some dry ones on top for you, sir.”

Questions such as “can it be undone” or “can I manipulate this” are all part of the learning process as our students engage in play with loose parts to investigate the phenomenon of transformation.

“Okay, great!” agrees Jose. “Can I have lots and lots of the red flowers on top, please?”

James comes running over to join the play. “What smells so delicious?”

“Acorn soup!” the children shout in a chorus of excited voices.

Our sensory-play kitchen is alive and well!

Sensory play activates and engages the senses—including touch, smell, taste, sight and hearing—while promoting the development of fine-motor and gross-motor skills.

When children engage in sensory play, they build new neural connections. These connections lay the foundation for language and motor development, creativity and essential life skills such as problem-solving, decision-making and memorization.

Imagine all of this cognitive development arising from a pot of acorn soup!

Acorn soup—or any magical, mystical concoction—can help children develop an understanding of math concepts in myriad ways, but most obviously through the use of mathematical language.

Imagine children mixing materials and discussing whether or not they should add more flowers, herbs, sticks, stones, pine needles or bark.

Quantity is a central concept in mixing. So it makes sense to incorporate pots and pans of all sizes, as well as measuring cups, to stimulate inquiry-based learning about quantity and volume, as children ask questions such as “How much should we add?” or “Do we want it to be thick like stew or thinner like soup?” It’s all part of building a child’s math vocabulary.

I could line up six young chefs to cook up pots of acorn soup and no two “recipes” would be alike. Children love to direct their own learning as they observe the “cooking” process and evaluate the ingredients that will make the best pot of “soup.” This is critical thinking at its best!

Whether you are cooking for play or actual consumption, it’s important to give children their own pots, bowls, measuring cups and utensils. Watching a friend cook is just not the same as engaging in hands-on, inquiry-based learning.

Real pots, pans, spoons, measuring cups and utensils help to “keep it real.” I delight in finding miniatures of good-quality cooking utensils. I love to use small stainless steel bowls. They are just the right size and they are affordable and easy to find at thrift stores. The same applies to measuring cups and spoons. Go with the stainless steel versions whenever possible. They always present well and they are sturdy and stain-resistant.

Children who are constantly engaging in “science experiments” or cooking up concoctions such as acorn soup are often exploring the transformation schema.

A schema is a repetitive pattern of behavior as children explore the world around them. Children who engage in the transformation schema will be fascinated by objects and their potential for transformation.

Play in this schema can be as simple as the transformation from dry to wet, from empty to full or from solid to liquid. Encourage children to investigate questions like these:

“How does this object change when I add water?” 

“Does the color change?”

“Does the texture change?”

“Does it smell different?”

By identifying and supporting schema play, you can tap into children’s interests and instincts while deepening and intensifying play and learning experiences.  

This is what STEM looks like! These preschool play moments pave the way for later learning in science, technology, engineering and math.

Experiences like these are integral to our mission here at Early Math Counts. Math is everywhere—in everything that we do with children and in every classroom activity. But we need to make the most of these math learning opportunities.

“Eleanor, is the soup ready yet?” Tucker asks from the other side of the yard. “How long does it have to cook?”

Ah, the ever-important gift of time. These periods of uninterrupted play stimulate brain development in a big way while enhancing children’s understanding of how the world (and math!) works.

So get your soup on!

“LOOK! We have icicles!”

“Can I have one?  I need one!”

On this brisk winter morning—much to the children’s delight—nature has given us the gift of icicles. The children’s fascination with these frozen treasures leads to an abundance of “teachable moments” as we engage in some STEM learning while getting some fresh air and exercise.

Soon we are counting, sorting and measuring the icicles. I can practically see those little brain synapses firing as the children use their senses to investigate the properties of the icicles and revel in the joy of being able to choose, hold and taste their STEM lesson for the day.

“My icicle is longer than yours!”

“I like the little icicles! They fit in my mouth better!”

“I like the thick ones, they last a long time! Look how fat mine is!” 

When I hear my students discussing size, comparing attributes and sharing their math vocabulary with their friends, my heart just soars. Mathematical language is one of the strongest predictors of children’s early mathematical success. Whenever children discuss relative concepts, they are doing math!

“Aww! I dropped mine and now it is in little pieces!” Janelle wails, holding back tears.

“They still taste good!  Now you just have lots of icicles!” says the ever-optimistic Claire. “Before you had one, but now you have more! You have 1, 2, 3, 4, 5!  You have five icicles!”  

Claire touches each icicle as she counts. The ability to count in sequence and use one-to-one correspondence to determine the number in a set is known as rational counting.

Janelle has the ability to rote count, reciting the sequence in the correct order without an understanding of one-to-one correspondence or the concept of cardinality (the number of elements in a set). “I do have five!” she shouts.

“Look, I can drop mine and it doesn’t break!” yells Owen as he drops the thickest icicle to the sidewalk, only to have a few pieces chip away.

It is difficult to ask children to compare quantities if they don’t know what “more” or “less” means. If they can understand “before” and “after,” they are more likely to know, or be able to understand, what number comes after four. When children learn this language in a math context, they are ready to move on to more advanced mathematical concepts. We are building our math foundation!

“How did you make these icicles? We don’t have them at my house,” asks Rowan as she chomps on her icicle. 

“I know!” chirps Robyn. “When the sun warms up the snow on the roof it melts and turns the snow into water and the water starts dripping and then it gets cold again and makes an icicle! “

We take a long look at the ice melting off of the neighborhood roofs and other inclines and see that the dripping has indeed created icicles. We discuss how warm temperatures melt the snow and that is why our clothes often get wet, even when the snow is frozen solid on the ground. Now we have science! I love it when our play leads us right down the path to new STEM experiences and investigations.

“Oh, when our hands are warm in our mittens, it melts the snow? I never knew that!” Logan has processed the information in a way that many of his younger friends don’t have the brain development to do. He seems quite astounded by this realization. Together, we hypothesize which icicles will melt faster or whose icicle will get eaten faster.

Then we swap out our wet mittens for dry ones and hunt for more ice to expand our STEM  vocabulary.

Discussions about the weather are often rote and meaningless in early childhood classrooms. Classroom activities that involve calendars and weather patterns can be boring for young children because they are removed from the actual seasons and weather events.

But bringing the children outside to experience the weather firsthand or bringing the snow inside to be investigated on a water table is interesting. Involving the children in hands-on investigations is a much better way to teach concepts such as “winter” or “cold” than directing a child to walk over to a window and report that “It is snowing outside.”

During this busy holiday season, give yourself and your students a chance to escape the heated classroom and venture into the great outdoors to breathe in some fresh air and find your curriculum in the natural world.

I promise you that this approach will lead to far more STEM learning than talking about the weather during circle time!

Truth be told, I did not write today’s blog.

Written by past blogger Jen Asimow, this post dates back to December 2014. Although seven years have passed, Jen’s words still ring true and remain relevant.

Her classic post, Top 10 Ways to Keep Calm This Holiday Season, is a welcome and much-needed reminder that we can find and cultivate calm as we weather the storm of COVID variants, holiday parties, family interactions, travel schedules, cooking, housecleaning, holiday-gift shopping and the dreaded supply-chain disruptions that threaten to derail shipments of eagerly awaited holiday gifts.

We are the constants in the lives of young children and—like most things that pertain to early childhood—we need to keep in mind that “less is more.”

Keep it simple and cut the curriculum in half this month if necessary.

As educators, we know that this month is crazier than it needs to be. So be kind to yourself, your staff and your students. Many programs simplify life by celebrating the seasons and removing all of the “themed” expectations that are scheduled around the holidays.

So take a deep breath, resolve to take the road less traveled and read Jen’s post. With COVID adding an extra layer of stress this holiday season, you’ll be glad you did!

Top 10 Ways to Keep Calm This Holiday Season

by Jen Asimow

December 3, 2014

Unless you work in a faith-based program, the holiday season should be almost non-existent in your classroom. Some of the December holidays are rooted firmly in religious teachings and others are celebrated by specific cultures. None of them have a place in diverse and publicly funded programs.

That does not mean that we should ignore them altogether. Children will arrive each day with stories about the comings and goings of extended family members, hopes for expected gifts or reasons for missed school days. They may be exhausted, irritable, bleary-eyed or wrung-out. They may be overly excited or revved up. All of these emotions will require a steady hand and a caring ear.

This is the time of year when hopes are inflated and dashed, when tummies hurt from eating too much and when bedtimes are ignored and exhausted children still have to get up and get to school. So I have come up with my Top 10 List for Keeping it Calm this holiday season.

“Hey everybody! Look at all of the tomatoes that are ripe today!” shouts Jacob to the gang.

“Can we eat them for lunch? Can we?” asks Lucus.

“Can we eat them now?” pleads Elizabeth.

It’s early September and preschoolers around the country are learning about apples, but we have tomatoes at our fingertips. The same tomatoes that we planted in the spring, watered, watched and then forgot about and ignored. But today these plants are full of red, ripe, juicy tomatoes. For the foreseeable future, our curriculum will revolve around tomatoes!

There’s been a lot of talk recently about curriculum themes and how they fit into early childhood education. So much of the learning that takes place in early childhood settings is spontaneous, rather than intentional. This doesn’t mean that early childhood educators shouldn’t be intentional about their curriculum development. They should. But great teachers are always willing to set their planned activities aside to seize a great learning opportunity when it arises.

I call these unplanned learning opportunities “teachable moments.” In so many ways, the child is the curriculum. By observing our early learners closely to see what ignites their curiosity, we can identify and build on the teachable moments that we encounter throughout the day.

Once we’ve identified a teachable moment, we can make the most of these spontaneous early learning adventures (and meet our early learning standards) by sharing our insights and asking questions that encourage children to dig deeper and make more connections as they engage in rich, authentic, hands-on learning that only looks like play.

After we engage in these impromptu investigations with our early learners, we can share the fruits of their learning adventures with parents and administrators, so that they can begin to understand how teachable moments can be harnessed to help prepare young children for the transition to kindergarten and success in the larger arena of life.

Soon, the stores will be filled with crisp, delicious fall apples, which will give rise to many of their own teachable moments, beginning with the letter “A.”  But today we have tomatoes, so we’re seizing the moment to harvest, sort, count, compare and investigate nature’s bounty!

It is only through genuine interactions and availability that teachers can identify these moments and act accordingly and spontaneously. Teachable moments require you to “think on your feet” and be flexible enough to stray from your planned path. If children’s interests take them in a direction that you hadn’t anticipated or planned for, you have to be ready to seize the moment and use it as a gift. Follow the joy of your students and your curriculum will develop organically!

“Look how many tomatoes are growing on this one vine!” Owen exclaims to his friends.

We are now collecting data and comparing attributes. Spontaneous discussions unfold as the children explore topics such as where the sun shines in the morning and which tomato plants get the most sunshine.

But how do the tomatoes ripen and turn red under all of those leaves? By observing, investigating and learning that living things grow and change, the children are building a strong foundation for future learning in earth science and life science.

We keep it simple. This type of learning is always developmentally appropriate because the children’s investigations are guided by each individual’s level of brain development.

“Avery, don’t eat them all!” cries one child as Avery pops a couple of freshly plucked tomatoes into her mouth.

We are exploring the concept of “many vs. few.”  But some of the children are too young to care about this concept and just want to experience the sweet deliciousness of a ripe tomato straight from the vine.

Our tomato harvest has all of the hallmarks of a true STEM learning adventure: investigation, discovery, collaboration and discussion. The children are learning through their senses: the visual task of surveying the tomato plants and comparing and categorizing the tomatoes as unripe (green or pale orange) or ripe and ready for harvest (deep orange); the tactile pleasure of separating a plump ripe tomato from its green stem; and the delicious sensation of biting into a tomato, still warm from the sun, and feeling it explode on the tongue. All of the goodness of nature and little brains in motion!

While two-year-old Lauren is more focused on picking the tomatoes and filling her bowl, some of the preschool-age children are busy trying to collect as many as possible. “Look how many I have!” squeals Linnea. “I have more than you!”

As the children explore the physical properties of the tomatoes, we are suddenly counting, estimating, comparing attributes and organizing by color and size. We have vocabulary and math flowing off of the children’s lips, which are stained with the juice of the ripe tomatoes. We are meeting our early learning standards—and the children are developing their own curriculum as they go!

Children construct their own understanding of the world when we provide them with a rich learning environment (in this case, our tomato garden) and ample time to explore, discover and investigate. We want children to think for themselves and not simply follow a preconceived curriculum or theme.

By taking advantage of authentic learning experiences in sensory-rich environments, we are setting the stage for the natural integration of early learning standards and successfully incorporating STEM knowledge into the daily lives of our early learners.

When you foster the development of a creative learning environment where children can find joy in learning, you will discover that your curriculum and lesson themes will spontaneously arise. In other words, let the children lead and the curriculum will follow!

Once the children have “followed their bliss,” introduce the books and thematic materials that support their interests. Build on their energy, enthusiasm and inquisitiveness.

If you head to the tomato garden, I think you’ll agree: early childhood STEM education has never tasted so good!

As I look around me, I see busy, contented children. Jimmy and Tali are seeing how high they can stack their rocks. Eve and Noa are creating a tea party for fairies near the sandbox. Eleanor and Salli are creating homes and meals for the squirrels who frequent the rain garden. Everyone is happy and learning. We call this a “play buzz.”

When I stop and take a closer look, I see that the children are not only playing happily, but working on math and science early learning standards through play with loose parts.

Architect Simon Nicholson, who developed the theory of loose parts in 1972, believed that loose materials that could be carried, combined, rearranged, lined up or taken apart and put back together in multiple ways provided more opportunities for creative play than static or fixed materials and environments.

Loose parts are materials that can be used alone or combined with other materials (Kabel, 2010). By creating opportunities to introduce math and science concepts—along with observations, predictions and data collection through loose-part play—we allow our students to experiment and work their way through their STEM explorations.

In outdoor classrooms or family backyards, educators and parents are discovering the beauty of loose parts in children’s learning and play experiences. The environment IS our curriculum. When we add natural elements to play areas, we create STEM-rich environments with myriad opportunities to solve problems in deep and complex ways.

As more and more classrooms and families return to the outdoors, simply giving our children the gift of time will facilitate STEM learning. This type of play comes easily to young children and can be far more productive than the worksheets, number cards and memorization activities that may be too advanced for your earliest learners.

We like to think of loose parts as acorns, bark, dirt, fabric, feathers, flower petals, leaves, moss, pebbles, pinecones, pine needles, rocks, sand, seeds, shells, sticks and whatever else may be native to your region.

We rarely take walks without bringing home all kinds of loose-part “treasures.”

Use what you have. If your loose parts are small and your early learners carry them around in containers to create “things” with, they are still playing with loose parts!

Take advantage of what you have around you and use these loose parts to set up a STEM-rich environment. We also use blocks, people, animals and other manipulatives. Loose parts can range from dramatic play props to toy cars to pots, pans and pouring devices. If your environment doesn’t already contain a collection of loose parts, I strongly suggest that you add them. Then stand back and observe your early learners to see how their play is transformed!

The beauty of loose parts is that they can be moved, which gives children the power to create new learning adventures every day. When materials are displayed in visually pleasing ways, this sends a message that you respect the materials and the creativity that they inspire.

Storage is another important piece of the loose-parts puzzle. A well-organized storage system imparts a sense of order and helps the children access the parts more easily. Children need to know where the loose parts are stored to be able to design their play experience—and to put their materials away when their project has been completed.

Outdoors, we use galvanized buckets, plant containers, crates or other containers for loose-parts storage. Use your imagination. I can tell you from practice that the happier the container makes you, the more relaxed you will be with loose parts.

Your outdoor storage will be more successful if you carefully determine the placement of your storage before you begin. If you move the storage every day, it will cause confusion.

Also, I know that some people think that more is better with regard to loose parts. But loose parts encourage divergent thinking (a thought process used to generate creative ideas by exploring a variety of potential solutions). So less is actually more.

Also, be aware that your buckets and baskets will likely get dumped out and used as loose parts instead of storage containers.

That’s a struggle for me. Usually, it means that I need more containers for the children to use in their loose-parts play. I recently added colanders for outdoor loose-parts storage. This has been a game-changer. Rain and snow drip through the holes, allowing the loose parts to drain and dry quickly. Look for them at your local resale shop or scout some out at garage sales to start your collection. They are truly the ideal container for outdoor storage.

Indoors, I try to keep our natural loose-part materials in wood bowls or sturdy baskets that are soothing to the eye and create a sense of order and tranquility.

STEM is all about discovery and exploring the world around us. When our early learners ask questions or wonder how or why something works, they are building a STEM knowledge base. So create an environment rich in loose parts and let the learning begin!

Document the children’s progress as they work through their theories, predictions and observations. You will witness design thinking, cause-and-effect epiphanies and collaboration between children like never before!

I recently grabbed our dusty box of beanbags off of the top shelf of the closet and took the beanbags outside. We rarely played with them indoors, so what was I saving them for?  If a beanbag gets lost or forgotten under the plants and soaked in the rain, who cares? At least it has been played with.

Now that the beanbags have been relocated to our outdoor play space, they have been used daily over the past few weeks. Recently we created a new beanbag game that laid the foundation for later STEM learning.

We currently have a full group of children who can pump on the swings, which is great—unless you have more children than swings, like we do. So I brought out the bucket of beanbags and placed it on the edge of the sidewalk. 

Then I picked up a beanbag and gently tossed it in the direction of my swinging friends. The kids loved the idea and it was GAME ON!

Now mind you, the swings were a good 12 feet away from that sidewalk—far enough to ensure that none of the children would be strong enough or accurate enough with their beanbag tosses to actually harm a friend.

“Hit me! Hit me!” hollered the members of the swinging gang.

“I want to play!” shouted the rest of the gang.  AYE YAE YAE!  What had I started?

What I had started was a new game that quickly became a favorite. No one has been injured, few have been hit and the cooperation and turn-taking is incredible!

Our rules were simple:

1. Throwers had to stay on the sidewalk.
2. No creeping up on the swingers.
3. Only throw one beanbag at a time.
4. When all beanbags have been thrown, yell, “SWITCH!” and the swingers must stop.

When the swingers stopped that first day, there was a mad rush by all to pick up the beanbags and put them back into the basket for the next round. WHAT in the world? I NEVER see this type of energy and enthusiasm during usual pickup times!

I encouraged the new group of throwers to take a water break to give the new swingers time to get up to speed before the throwers started aiming at their targets. And then we repeated the cycle for a good 20-30 minutes before the children exhausted themselves from all of their throwing and pumping.

We had overhand throwers and underhand throwers. I watched as they tried different techniques and shared theories with each other on the best time to throw the beanbag depending on where the swingers were in the air. This is physics! This is math and geometry and plain old fun!

Investigations into physical science and engineering through this type of play give young children a chance to explore and control physical phenomena and develop a practical understanding of the laws of physics— all while giggling with their moving-target friends.

This activity also teaches children about risk-taking and trust building. You trust that your friend won’t hurt you, but you definitely take the risk of possibly getting hit. Scary but fun!

As the game evolved, new ideas were added to the play. Sometimes children called out the number or  letter printed on the beanbag or grabbed specific colors. One three-year-old consistently looked only for beanbags labeled with letters that had meaning to him: the first letter of his name or the names of his two siblings. (I later found three beanbags labeled with those letters hidden in a secret corner of the yard. Ha!)

Physically, our beanbag throwers were building up the muscles of their dominant hands, which they will use in future academic settings. They were also working on STEM concepts such as distance, accuracy, speed and force. We throw these wonderful science words into their play to build up their STEM vocabulary and lay the foundation for a deeper understanding of scientific concepts. Meanwhile, our swingers were  focusing on the trajectories of the beanbags headed in their direction and making predictions about when and where they would hit, while strengthening their core muscles for future desk and circle time.

OH, you want learning standards? We’ve got those covered too. We count, subtilize and build our math vocabulary. We measure and estimate distance. We make predictions and modify those predictions based on experience. We use our science skills to explore the physical properties of objects and experiment with force and motion. The list goes on and on and there are so many ways to adapt this game. So grab your beanbags, head outdoors and let the playing and learning begin!

“Will the children be kindergarten ready if they spend their days playing outside?”

As educators, we are often asked about kindergarten readiness by nervous parents who want to give their children the best possible start in life.

It’s important for parents—and educators—to understand that there are endless opportunities for deep learning when children are connected to nature. Young children learn primarily through their senses. The natural world—with its stimulating and constantly changing elements—provides the ultimate sensory learning environment.

When children explore the world through sensory play, they are actively building new neural pathways, which is crucial for brain development. When we slow down enough to observe this process, it’s easy to see the learning that takes place, and the social skills that are being developed, as the children collaborate on projects in the great outdoors.

On an unusually warm day in May, the boys in our program are busy building a large castle in the sandbox. This may look like nothing more than sandbox play, but there’s some deep learning going on here as our castle architects lay the foundation for future academic success.

“We should build a moat!” declares Joshua.

“Yeah, a moat!” agrees the gang. “We definitely need a moat!”

With these words, the digging begins. Before long, the castle builders decide that it’s time to add water to the moat. We have plenty of buckets at our center, but today most of the buckets are already in use.

Looking around for a way to transport the water from the pump to the sandbox, the boys settle on a nearby piece of fabric from one of their forts.

We’re all hot, tired and likely a little dehydrated at this point. A glance at the clock tells me that it’s almost closing time. But who am I to redirect the boys by pointing out the empty bucket next to the fence?

I watch as the boys carefully stretch the material out and center it beneath the pump spigot to catch as much water as they can. Asa begins pumping and, to my astonishment, the fabric holds the water without any leakage.

WHAT in the world?  I’m marveling at this unexpected development when it occurs to me that the cloth I’d purchased from the resale shop is actually a waterproof fabric used in hospital settings.

When I ask the boys if they were aware that the fabric was waterproof when they grabbed it, they respond with a question of their own: “What does waterproof mean?”

I try to explain that waterproof means that the water will not flow through the fabric. But there are times for discussion and times for action—and the boys are already focused on the next step in their plan.

First, they gather the corners of the cloth, taking care to keep the water from gushing out the sides. Then they make their way gingerly across the yard to the sandbox and carefully place the fabric in the moat.

I realize at this point that the boys had deliberately ruled out the use of buckets because they needed a flexible, waterproof liner for their castle moat.

They had assumed that the fabric they chose would hold water and, at the same time, conform to the shape of the moat. Wow! They were way ahead of me!

The boys did eventually make multiple trips to the pump to fill some buckets and add more water to the moat. But they knew that the bucket wasn’t the best tool for the initial phase of moat construction. Silly me!

This is just another example of the importance of giving young children sufficient time to engage in deep play and problem-solving (without any interference from those of us who think we have all of the answers), as well as the importance of loose parts in creative play.

Look at the delight on their faces! Okay, so the castle architect on the far right in the photo below seems to be grimacing at the weight of the load, but the other two look pretty thrilled with the success of their mission!

When we look at children playing in sand, what are WE missing? They are busy designing, creating, collaborating and communicating. They are adding and subtracting, working with shapes and molds and inclines and declines. They are adding water to change the nature of their building material. They are using spatial awareness and math and science vocabulary. They are theorizing, hypothesizing and collecting data. They are engineering and deepening their knowledge—all while playing in a box of sand!

This is the ultimate in STEM learning. Give them as much time as they need. Let them play. Add fabric to your play centers. You never know where their outdoor play will lead them—and what YOU may learn in the process!

“Look everybody! It’s a luna moth!” Rowan’s enthusiasm for any insect on the planet always keeps us on our toes, but today’s discovery has everyone jumping for joy.

When May rolls around, we are often blessed with the arrival of a luna moth on our classroom’s backdoor screen. Upon landing, the luna moth clings to the screen, affording us hours of enjoyment as we get a close-up look at this lovely winged creature.

Luna moths are nocturnal. Like many moths, they are attracted to light, which is why they are often found on screen doors beneath porch lights. Luna moths are easy to identify by their white bodies, long pinkish legs and large, translucent lime-green wings.

Our back door gets a lot of use, so whenever I find a luna moth clinging to the screen, I joke that there are much more peaceful places for this winged creature to stop and rest awhile. But I am always thankful that Mother Nature has blessed us with this learning opportunity.

Today’s luna moth discovery has set our curriculum in motion, with Rowan as our guide. “See those big, beautiful eyespots and that long tail?” she asks. “Those eyespots will trick predators into believing the moth is bigger than it really is.”

When Rowan asks if we can measure the luna moth’s wingspan, we carefully measure the width of its wings. Four-and-a-half inches—almost five!

“Will it bite me?” asks four-year-old Parker.

“No,” laughs Rowan. “It doesn’t have teeth. It doesn’t even have a mouth! This luna moth will only live for seven days. It doesn’t drink or eat. It is only alive to make new baby moths.”

This is pure preschool science—and the children love it! The rest of our day will be spent discussing luna caterpillars as Rowan continues to educate us. At nap time, we will bring out photos of other luna moths, as well as books. Our favorite book at the moment—Beauty the Luna by Julia Welch and Jymann Merritt—is a beautifully illustrated story about the life cycle of the luna moth.

In the coming weeks, we’ll be on the lookout for the luna moth’s eggs: tiny white ovals attached to leaves with a sticky brown adhesive coating.

     
  We’ll also be keeping an eye out for luna moth caterpillars (below).

Rowan’s love of insects is likely due to the influence of her mother, an associate professor of biology who studies insects. Lucky us! We have our own entomologist just a text message away!

Rowan’s mother observes our luna moth over the course of the week and alerts us when the moth is nearing the end of its life cycle. She gently removes the moth from the screen door and guides our young learners through a close-up investigation of the moth’s anatomy.

We count legs, antennae and eyespots. We observe the luna’s markings and compare them to different shapes we’ve learned about. Each child has a chance to hold or touch the luna moth before Rowan’s mother encourages the moth to fly to a more peaceful haven for its final hours.

Last September, we received an email that a graduate of our program (second from right in the photo above) had found a luna moth caterpillar and created a habitat for it with a repurposed Ikea clothes hamper.

As the luna moth caterpillar munched on a meal of walnut, hickory and birch leaves, this junior entomologist told her family that, when threatened by a predator, the caterpillar would rear up on its hind legs and make a clicking sound before puking out a bad-tasting liquid. (We often find that the grossest facts are the most likely to be retained by little brains.)

Within days, the caterpillar had spun a cocoon inside the hamper. Leaves and small branches are often woven into luna moth cocoons to camouflage the cocoon and protect the vulnerable larvae as they metamorphose into moths.

This particular luna moth caterpillar spun its cocoon on the underside of the tag in the hamper below!

Then the waiting began. Caterpillars who cocoon early in the season generally emerge as moths after three weeks, but many weeks passed without a metamorphosis. The hamper was put away for the winter and the family assumed that their luna caterpillar had died.

When spring arrived, the family pulled the outdoor play items out of storage and returned them to the yard (including the hamper—cocoon and all).

On May 20, a full eight months after the caterpillar had spun its cocoon, a luna moth emerged! What happened? It turns out that, if the caterpillar spins itself up in a silken cocoon in late autumn, it “overwinters” and does not emerge until spring.

Opportunities like these may crawl or fly into your classroom on any given day. This is one of the great joys of early childhood education. When STEM opportunities arise, put your planned curriculum on hold and take advantage of the rich learning environments that are literally right outside your door. Incorporate math into the learning experience as you introduce concepts such as size, shape, probability and data collection. Tap into technology for a wee bit of research. Kids LOVE facts that they can retain and share with others. Meet your early learning standards for science when you add topics such as weather, seasons, earth science and life science.

Sightings of luna moths signify new beginnings. But there is a bittersweet symbolism in the arrival of these magical creatures in May, just as our oldest students are about to leave us and move on to kindergarten in the fall.

Nonetheless, the arrival of a luna moth brings endless opportunities for STEM investigation and exploration. Keep your eyes peeled for this magical creature during the month of May, and let the learning begin!