“One, two, three, flip!” 

“I win!” shouts Matif.

Remember playing War as a child? It’s simple and fun and it teaches young children how to win and lose without a lot of drama.

I love playing cards with young children because that little deck helps foster the development of early math and social-emotional skills in a big way.

When I play War with very young children, I often pull out the face cards and any card higher than a six. Depending on the ages and developmental levels of my students, I may even pull out the aces because it’s too difficult for young children to associate the letter “A” with the number “1.”

Start by dealing the cards evenly between all of the players, stacking the cards face down in front of each child. 

No peeking allowed!  On the count of three, each player will flip the top card over into the center of the table, face up.

“One, two, three, flip!”

A chorus of young voices chants in rhythm as our game continues.

“I have a five,” shouts Mable. “That’s bigger than your two, so I win!” 

Compare the cards played. The highest card wins the hand. The winner takes all of the cards played in the round and adds them to a new stack of “won” cards. 

One, two, three, flip!”

“Ah, you both have a six! War!”

When there’s a tie between the two highest players, you have a “duel.”

To play a duel, the two players each place three cards in the middle of the table, face down. Then they each lay down another card (the fifth card for this round). This card should be facing up. The highest card wins, and the winner takes all of the cards from this round and adds them to a new stack.

“One, two, three, flip!”

I watch as a four and a three get turned over by the players in the duel.

“Ah, you won all those cards!” says the child with the losing hand. “Lucky you!” 

When children are playing cards, this is a great time to observe their number sense. Can they identify the numbers by name? Can they determine which number is higher? Can they follow the rules?  When the cards match, can they count out the three additional cards that they will need for a duel?  

Play until your main stack is gone and then count up how many cards the players have in their stacks of “won” cards. The player with the most cards wins. Once the children have mastered the cards through the number six, I will add the sevens and eights back into the deck. Later, I will add in the nines and the tens.

Many children will be able to play a full game of War by the time they reach kindergarten—face cards included. Keeping it simple in the beginning is a great way to assess your students’ number recognition skills and value development.

As children play this deceptively simple game, they are developing their number-recognition skills and beginning to grasp concepts such as number value, greater than and less than.

They are also learning important life skills such as how to follow rules, take turns and take their turns quickly without making the other players wait too long. That’s a lot of learning for a game that fits in your pocket! 

We also want to teach children how to win and lose graciously. I love playing War because it’s a game of chance and everyone has an equal chance of winning. Because each round has a winner, we are practicing the win/lose concept over and over again in rapid succession. There isn’t time for the winners to jump up and do a victory dance or the losers to break down and get weepy. The same child will not win every round, which gives every child many opportunities to practice good sportsmanship.

There’s a reason that children have enjoyed playing War for generations. It’s fast and fun and a bit addictive. So grab a deck or two, play a few rounds with your early learners and call it your math curriculum for the week. You’ll be teaching invaluable life lessons along with those early math skills!

“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!

“Hey, Hudson! How did you do that?”

Eleanor is amazed at Hudson’s success as he races a car down the ramp. This is the same car that she couldn’t get to stay on the ramp just minutes earlier.

I listen as Hudson turns the car over and explains, “See those wheels? The front ones were bent. I had to take my finger and straighten that part that connects them. That is why it was going crooked.”

Eleanor is completely engaged in the moment as Hudson instructs her on the physics of motion.

We have a group of kids at our center who have grown up together, developed great friendships and built a strong early math and science foundation. Science skills enrich children’s math skills and concepts through hands-on experiences. Math is used to construct and understand data that is collected through observation. You can do math without science, but you can’t do science without doing math.

In the past few weeks, I have been reminiscing about how this group’s understanding of concepts has grown right along with their physical development. We are currently ramp and incline crazy, an activity that has piqued the children’s interest in cycles over the past few years.

Recently, inclines have dominated our play once again, and we have been doing a lot of investigative activities with ramps of all types and sizes. Experiments with force, speed and motion foster the development of scientific-inquiry skills and offer endless math opportunities, as well as great fun!

When our young friends play with inclines, they often try out new ideas and techniques. I love to listen to their theories as they engage in this rudimentary scientific exploration while mentoring and encouraging one another. Their knowledge continues to grow as they experiment and observe the outcomes. This is data collection!

Once again, we are meeting those early learning standards through long periods of uninterrupted play. Not all of their ideas will work. When they don’t, this leads to deeper communication and collaboration as the children use what they’ve learned to modify their techniques.

I watch as they observe each other’s successes and failures and try to improve on their ideas and methods to achieve their goals.

Simply placing the basket of beanbags at the top of the slide is all that it takes to encourage collaboration, cooperation and a lot of giggles. Activities such as these prompt children to explore their environment and use what they learn to design new experiments and test out new ideas as they make sense of the world around them.

By offering opportunities such as these, we are laying the foundation for the mathematical concepts and skills that they will need to perform later scientific investigations.

Ramps and Inclines provide a treasure trove of opportunities to meet your math, geometry, measurement and number standards. I love to watch the children at my center as they make predictions and then test out their theories. Sometimes with success, sometimes not so much. By reflecting on their experiences, the children are constructing their own understanding and knowledge of how the world works. Counting, classifying, measuring and comparing are some of the processes that can take place when we allow long periods of uninterrupted time for exploration and discovery.

Our play experience with ramps and inclines is a perfect example of STEM learning. The physics involved in creating stable structures and moving objects in various ways will enable us to meet our science standards for the day. Engineering happens when the children design their structures or change the way they move their objects. When they draw conclusions about how objects move through space, make predictions and collect data, we have wrapped up our STEM lessons in one pretty little package of play!

Best of all, this activity is developmentally inclusive. All ages can engage in incline play. It took less than a day for our youngest learner to figure out that the object he drops from the top of the incline will slide to the bottom. This activity keeps his attention for long periods of time and his enjoyment never ceases as he conducts his incline experiments again and again.

The joy of watching young children join in the math and science play never gets old. So grab a ramp and a few young friends and start your own math and science club!

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!

“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!

“AUGGGHHHH!” I hear screams, a crash and giggles galore.

The joy of Magna-Tiles® has returned to our ever-popular window-stacking play. When these colorful magnetic tile mosaics come crashing down from the window frame, the children respond with laughter and joy. By contrast, the collapse of three-dimensional block formations often elicits groans and tears.

Something about the suspense of the build (and the challenge of stacking the magnetic tiles higher and higher without triggering a collapse) keeps the children coming back to this activity time and time again.

For anyone unfamiliar with Magna-Tiles, they are magnetized tiles of different shapes that can be used to build the most amazing creations. We have purchased other magnetic block sets, but the children had difficulty figuring out the polarization or were frustrated by the lack of versatility. Ultimately, those more expensive sets were abandoned to collect dust in a corner while the children spent endless hours playing and learning with the Magna-Tiles.

Is there a more perfect block than a Magna-Tile? If I were stranded on an island with a group of preschoolers, this would be on my top-ten list of must-have learning tools. Heck, it would be on my top-three list. These are, without a doubt, the favorite block in our program. What’s not to love? Magna-Tiles build confidence and fuel hours of creative play. Our only problem with Magna-Tiles is that we never seem to have enough!

I read somewhere that you know you have enough blocks when there are still blocks on the shelves. I’m still not sure I have enough Magna-Tiles on any given day, and I always find myself purchasing more. (Full disclosure: I often purchase PicassoTiles, which are less expensive, equally rugged and nearly identical to my original Magna-Tile set. So, if your program is on a budget, don’t hesitate to buy this less expensive set.)

Magnetic tiles are a STEM classroom delight. We have math opportunities with shapes and colors, counting, blending colors, angles and geometry galore! We have science and engineering as we explore different designs and building techniques. The magnetic feature opens doors to design and construction options that regular wooden blocks cannot provide.

“What color is your tree?” Harrison asks his best friend, Jack, as they use their magnetic tiles to change the colors of the scene outside our window.

The collaboration continues as the two boys follow their creative impulses and develop their ideas.

Then Jack proposes a new challenge. “What if we try a triangle this time?”

The boys determine that the results will be the same regardless of the shape. I am convinced that the children’s understanding of different shapes has been greatly enhanced by the use of these magnetic tiles. Magnetic tiles are the perfect educational tool for teaching all things geometric!

I also love to observe the children as they engage in problem-solving when they are confronted with a shortage of large square magnetic tiles. They quickly determine that they can create the same shape with four smaller magnetic tile squares.

Magnetic tiles also lay the foundation for an understanding of sets and quantities, as well as concepts such as location and ordinal positioning as the children expand their STEM knowledge and vocabulary.

“Jack, do you think we can add this square and it won’t fall down?” asks Jack’s twin sister, Eve, who is working through her predictions and collecting data on what works and what doesn’t.

I watch as Eve gingerly pries the corner of the bottom tile away from the window and triggers a structural collapse that brings all of the magnetic tiles tumbling down.

This investigation of “What happens if…?” is met with delight and infectious laughter from Eve’s peers as the building collaboration starts all over again.

“If we add this triangle to the top, the trees will turn green and look different from the red trees down here.”

Jack and Eve continue to pursue different avenues of learning with the tiles. One minute they are investigating colors and the next they are observing patterns or determining which shape should be added to the mosaic.

I’ve noticed yet another benefit of our window-frame magnetic-tile mosaics: The activity often brings children together who don’t naturally play side-by-side.

In other words, this group endeavor builds community. I am not sure if it’s a team effort of US versus the WINDOW BLOCKS or if it’s simply the contagious joy of the activity that makes everyone want to join in the fun.

When the temperatures drop below zero for days on end, I know that I can count on our magnetic tiles to lighten the mood and enrich our learning through play.

One more note: I have been known to remove the magnetic tiles from our play on occasion.

Why? Because I believe that magnetic tiles are so easy to use that they create “lazy builders.” This is just a personal theory of mine, but I’ve seen it play out over and over again. Sometimes the children in my program need to be pushed out of their comfort zone.

I do this by pulling out my wooden unit blocks, which require the children to perfect the balance and symmetry skills needed to build a stable block tower.

When those wood towers fall, I remind my wee ones that they are great builders and then I help them start building again from the foundation up.

When I rotate the magnetic tiles back into our play after a period of going “back to basics” with the wooden blocks, I nearly always notice that the children’s building skills have improved.

Try it and let me know your results. Happy building!

“I found an empty nest! Can we keep it?” Owen’s joyful discovery captures everyone’s attention.

Three-year-old Avery comes running. “Are there eggs?” she asks her older and wiser five-year-old friend. “Can I see?” she begs. “Please let me see?”

“There are no eggs, just an old nest. Can we please keep it?” pleads Owen.

After a quick glance to confirm that the nest cradled in Owen’s hands is not harboring a feathered inhabitant, I grant my permission.

Owen handles the nest gingerly before realizing that it is sturdier than it looks. After a few tugs and a few moments of studying the nest, he very gently hands it over to the others.

We have a collection of nests. We love to study the materials used to build each nest, as well as the nest construction methods used by different local bird species.

We also try to guess the type of bird that built each nest and how many eggs might have been laid in these cozy homes crafted from sticks, grass, leaves, string, mud and other found objects.

I watch Ave silently investigating and collecting data as she turns the nest in one direction and then another. You can almost see the wheels turning.

“I think the bird used some litter [drinking straws, food wrappers and other debris] to build this nest.” Ave giggles. “And there are like a million sticks in here!”

“A million?” I echo.

“Maybe more!” Ave theorizes.

This moment gives me a valuable insight into Ave’s nascent number sense. Connecting numbers to quantities is a skill that will continue to emerge and evolve with age and brain development.

“The bird added string—and look at this piece of wire she wove in!” shares Maya. “It’s lightweight but very strong. How long does it take her to make this nest? I think this nest is smaller than the others we have.”

This is how we set our curriculum for the day—by following the interests of the children. When we return to our indoor classroom, we will dig out our books to learn more about the various engineering practices that local birds use to build their homes and compare this newest nest to the others in our collection.

Living along the Mississippi River as we do, we are blessed with the return of our beloved bald eagles each winter and spring. From December to March, these magnificent birds migrate south from Canada and often make our area their winter home. Some even like it so much that they make it their permanent home.

In the fall and winter, the eagles rebuild their nests to prepare for the hatching of the eaglets. Eagles nesting in our area typically lay their eggs in mid-to-late February, and the eggs hatch by mid-to-late March.

Once the eggs have hatched, the female stays with the eaglets while the male leaves to find food for the female and her hatchlings.

The eaglets grow quickly and are ready to fly—or “fledge”—by late May or early June. A number of webcams have been set up by organizations in the area so that we can watch the life cycle of the eagles playing out before our eyes.

This is where I struggle. We are a screen-free environment. I know that we can link to so much learning with technology. I know that I need to stop being so stubborn. I am that old-school playground leader who hasn’t embraced the many educational benefits of 21st-century technologies.

We weren’t always screen-free—and I have fond memories of the year when we observed a wee bit of eagle life via webcam.

I hated the screen, but I loved learning about our local eagles. When an eagle brought a large fish to the nest, we were spellbound. But the fact that we’d been sucked into spending time staring at a screen contradicted everything that I believed in regarding early education—and I was overcome with guilt.

So when the first warm day of spring arrived, we created our own eagle’s nest in the center’s outdoor play area.

“Declan, how big is an eagle’s nest?” I asked, measuring tape in hand.

“Seven feet wide,” he responded. “What are you doing?”

I quickly measured out seven feet and put a heavy rock from the rain garden on the spot. The children began adding rocks until we had a circle that was seven feet in diameter.

For a few minutes, the children pretended to be eagles living in a happy little rock nest—until one perspicacious preschooler called me out.

“Wait! This isn’t a nest!” Asa declared. “We need to add sticks and leaves and yarn. We need more!”

“We do need branches and sticks!” agreed four-year-old Joshua.

“Over here!” directed two-year-old Gabe.

Game on! Now we were learning, creating and analyzing. We’d taken what we’d learned during our screen time and translated it into real-life, hands-on learning that met so many of the math and science standards that they would struggled to achieve on a worksheet!

This was when we grabbed our books and discovered that an eagle has a wingspan of 6-8 feet. We also learned that a mature eagle has 7,000 feathers, weighs 8-11 pounds and has vision so keen that it can see the print on a newspaper at a distance equal to the length of a football field. These are the details that young children are likely to absorb.

Because bald eagles are most active from sunrise to 11 a.m. as they feed along the open water of our locks and dams, this coincides quite well with our outdoor times. Lucky for us, they return to their roosting areas in the afternoon hours.

After lunch, some time spent browsing through eagle books and a nap, the boys made their way back out to their new eagle’s nest. If they build it, they will play in it. They had been playing there for a good long time when, sure enough, up in the sky, an eagle appeared!

Yes, a  real live eagle! Would she think this was HER nest? Could she see the boys in HER nest?

As the boys contemplated the possibility of the eagle swooping down and landing amongst them, they scrambled out of their nest in pure terror.

The eagle did not land in our nest. But, sadly, our frightened little learners never returned. I left the nest in place for over a week, and some of the younger children played in it, but the boys who built it kept their distance!

I often find that most of the fun is in the building phase of the project. The collaborating, creating, adding, subtracting, analyzing and evaluating with friends is actually the play for building kids. This is the good stuff that happens with play; enough time to engage in deep, investigative learning; and, sometimes, just the right amount of technology.

Take time to follow the lead of your students and see where their interests and curiosity take you. Then match their learning up with your early learning standards.

This link will take you to the Arconic Eagle Cam.

Full disclosure: The male eagle will bring food back to the nest. This could be a raccoon, a fish or a mouse. It is nature. It is graphic. It can be addicting or terribly uneventful at any given moment!

When we build nests of our own, we often use this Scientific American site as a reference. But if you’ve lingered too long on the Arconic Eagle Cam link provided above and feel guilty about overdoing the screen time, you can just WING it—pun intended!

Ha! Let’s get outside and play.

“I see the daddy cardinal, do you know where the mama bird is?” Four-year-old Noah, binoculars in hand, is busy counting birds in our outdoor classroom.

Are you aware that the annual Great Backyard Bird Count is coming up later this week? This is a great opportunity to create a bird-watching station and knock out some STEM and early learning standards while encouraging family involvement.

Mark your calendars for Feb 12-15 and join us for this fun and educational week!

February and March are good months for bird watching and bird counting in our program. This is a great way to accelerate STEM learning on days when below-zero wind chills make outdoor play impossible.

We have bird feeders set up right outside of our windows so that we can set up indoor bird-watching stations to give the children close-up views of their feathered friends.

We provide clipboards, books, binoculars and our abacus to help with the bird count. We also use this opportunity to teach our students how to tally on a tally chart. We reference the eBird website, which shares local sightings of different bird species.

I take the top ten birds sighted in our area on the eBird website and add pictures of those birds to our abacus. To do the same thing, just add your location to the eBird website and you’ll see which birds are sighted most often in your area. It’s quite fabulous!

We also like The Cornell Lab and the Audubon Society. I have the Cornell Lab Merlin Bird ID app on my phone to help us identify birds by their songs.

Your local U.S. Fish and Wildlife Service may also be able to provide free materials for bird identification. There is a big difference between bird identification books for children and those that were written for mature bird watchers. I would check some out at your local library or bookstore before purchasing.

This is a great opportunity to practice not only counting, but grouping by attributes or close observation of the differences between a downy woodpecker and a red-bellied woodpecker.

We try to keep a ruler nearby for our older children to use to determine whether they have spotted a six-inch downy woodpecker or a nine-inch hairy woodpecker. This offers the children an opportunity to use estimation and practice using real tools for observation.

This is also a great time to introduce Venn diagrams for clarification and documentation.

By creating a comfortable and inviting place for the children to birdwatch—complete with pillows, chairs and tables with baskets of binoculars—you can encourage them to slow down and observe more often.

By planting native plants in your outdoor classroom, you will also attract more birds to your bird-watching stations.

We remind our kids that outdoor birds are hard to spot but easy to hear. We ask them to close their eyes and point to where the song is coming from. I like to teach common mnemonics like the American Robin’s cheery up, cheerio, which can be picked up on almost any bird walk in the United States. Learn some mnemonics for common birdsongs here.

We have tried the inexpensive plastic binoculars from school-supply stores and toy aisles. They really didn’t work well and broke the same day that we brought them out. Smaller, child-sized binoculars are much easier for little hands to manage. Children enjoy using “real” tools and will treat them with much more respect than a pair of cheap plastic ones. I often teach them how to focus the binoculars to get a clear image. I place these binoculars in a basket, along with the identification books. We also stock our bookshelves with a wonderful collection of books about birds, nests and hatchlings.

We talk so much about STEM these days. This is one of the easiest and most magical ways to create a learning hub that can inspire young learners to engage in STEM exploration and discovery.

By participating in these learning adventures, you can learn right along with the children as you observe, ask questions, draw conclusions and discuss your findings with your early learners.

When we observe birds from our indoor birdwatching stations and then take those same observational skills outdoors, we have a deeper understanding of the birds we see and the birdsong we hear.

By adding the technology from the websites mentioned above and building bird feeders from oranges or peanut butter and seeds, we can include engineering in our learning adventures. We can include math as we count the number of birds arriving at the feeder and then subtract the birds that fly away. By grouping, measuring and comparing the birds, we can meet our early learning standards and benchmarks.

I hope you will join us in our Great Backyard Bird Count this year. Birds of a feather flock together. Come join the fun!

” Hey guys! Look over here! My magnet sticks to the bike!”

On this warm November morning, our magnetic wands have brought STEM learning to our outdoor classroom. By leaving the other magnetic materials behind, I am hoping to encourage the children to harness their curiosity and creativity for other forms of magnetic exploration. Opportunities like this allow children to learn independently, as well as collectively, as they explore on their own and then share what they have discovered with their fellow magnetic explorers.

This morning’s investigation introduces the children to scientific methods such as forming hypotheses, setting up experiments to test out their hypotheses, analyzing data and recording results. We have math exploration as they learn about spatial awareness, as well as math vocabulary building as they begin to understand and label concepts such as location and ordinal positioning—all in a morning of play with friends.

“Oh, wait! It sticks on the red part, but not on the black seat,” exclaims Harrison.

As the children race over to view Harrison’s latest discovery, I note with satisfaction that they have found their own way on this morning of STEM exploration.

“Why won’t it stick on the black seat, Harrison?” I ask.

“Because it’s not metal,” Harrison shares with the group.

“It’s not metal!” the other children repeat in a chorus of little voices. We are in that modeling stage of language this month. A comment made by one child is repeated by every child, like a group of enthusiastic parrots. This behavior has been making me a bit crazy lately. But, at this moment, I am grateful.

“Wait! This part is black but my magnet sticks here.” Harrison is thinking out loud, and his comment is met with silence as the other children test out his observation and come to the same conclusion.

“Wow, Harrison, I am confused. Why does your magnet stick on the black part there but not on the black seat or the black tires?” I ask.

“This black line is metal,” Harrison shares. “It is black metal.”

The other children parrot his response as the learning continues: “Yes! It is metal—black metal!”

Harrison continues to educate his peers. “The red part of the bike is metal and this black strip here is metal. The tires and the seat are not metal.”

Soon, the magnetic exploration moves to the swings, which leads to another deep dive into STEM learning as the children use their wands to determine which parts of the swingset are magnetic and which are non-magnetic. It is also a great opportunity for us to document our research and meet more Illinois early learning benchmark standards.

We use red and green tape to document our results. Magnetic surfaces are marked with green tape (go) and non-magnetic surfaces are marked with red tape (stop).

We could also record our findings on a clipboard, but this is a fun and visual way to document our data—and it is easier for the children to understand than checkmarks on a piece of paper.

This group doesn’t read yet—and drawing pictures would have slowed down the learning process. If you happen to have an artistic child who loves charts, this is a dream day for them. Make this child your research assistant!

I love it when children learn while moving, playing and sharing with friends.

Experimenting with magnets encourages children to learn by exploring, observing and figuring out how things work. A longer period of time for discovery gives our students more opportunities to learn. I look over at the stump circle and see Eleanor quietly working her way through a solitary study of magnetic fields. Eleanor is deep in concentration as she studies and researches, collecting data and reanalyzing the magnetic poles and the attraction of the multiple magnetic wands.

“It’s called a magnetic field,” I explain. Eleanor is working through her understanding and doesn’t look up from her investigation. I watch her speculate her way through different scenarios and then I try again.

“It’s invisible!” I whisper, and Eleanor’s head pops up.

“Who doesn’t love invisible?”  I continue to whisper: “It’s that invisible power called a magnetic field that is making your magnets push or pull each other. I love invisible.”

“It’s magic!” chirps Eleanor. “I can feel it pulling me!”

Eleanor smiles as she shares her understanding with me. It never gets old for me to observe the excitement and wonder that goes hand in hand with little brains making new connections and discoveries.

The next time you head outdoors with your students, grab the magnetic wands and let the invisible magic of magnetism lead them to a new understanding of magnetic forces and fields. If you’ve gone virtual this new year, magnetic play is a great way to get your little learners to venture out into their own backyards to get some fresh air and learn about magnetism through play.

Stay safe, my friends!