13B – Early Math Counts https://earlymathcounts.org Laying the foundation for a lifetime of achievement Fri, 29 Oct 2021 17:47:03 +0000 en-US hourly 1 183791774 Fort Building 101 https://earlymathcounts.org/fort-building-101/ https://earlymathcounts.org/fort-building-101/#comments Fri, 16 Apr 2021 01:06:57 +0000 https://mathathome.org/?p=12272   “LOOK!” screams a four-year-old with such joy that we know this isn’t a garden-variety “I want to share something with you” moment. As the gang rushes to her side, they come to a complete standstill, frozen in awe. Oh happy day! Some kind souls have shared a fort with the community! There before us […]]]>

 

“LOOK!” screams a four-year-old with such joy that we know this isn’t a garden-variety “I want to share something with you” moment.

As the gang rushes to her side, they come to a complete standstill, frozen in awe.

Oh happy day! Some kind souls have shared a fort with the community! There before us stands the most wonderful teepee-shaped fort that we have ever seen. Forts have been popping up all over town this year—and I couldn’t be happier about this trend.

This 14-foot high monument has sparked wonder and curiosity in all of us. We have stumbled upon a STEM adventure! This is math, science and engineering play that allows the learning to come naturally and at each child’s developmental level. This is also sharing. It teaches children that our community creates beautiful spaces to be enjoyed by all.

“Who lives here?” asks Liam as he bravely ventures closer.

“Can we go in?” questions three-year-old Madison, not sure that she really wants to.

We do go in, and the investigation into fort building sets us in motion for the day. Do you remember building forts when you were a kid? Did the memory of that fort just resurface? If it did, you retained that memory and are likely able to build another.

These are the moments that we like to create for our early learners. Hands-on learning enables children to take their understanding to a deeper level so that they can analyze the information that they have collected and then apply this knowledge when they create their own forts.

After giving everyone a turn to observe and discuss the masterpiece in front of us, we take a good hard look at the fort and investigate how it was constructed so that we can build a fort of our own.

We discovered this fort (above) while hiking in our neighborhood.

“I think this fort was started from that fallen branch!” Harper hypothesizes.

This leads to closer observation as we determine that this fort has sides that were built with sticks ranging in size from large to small. By leaning them against the main branch, the architects made the fort longer and wider. We begin to get a better sense of measurement as we visually estimate the length and width of the fort.

We always add a few sticks or branches to any fort that we discover, and today is no different. The older children quickly begin to add branches—an activity that reinforces our perception of the fort as a communal structure. When our younger learners hesitate, we reassure them that they really can’t go wrong by adding a stick or two.

“It looks like a triangle!” shouts Elizabeth. This declaration leads to an animated discussion about shapes and ways to incorporate doors, windows and other shapes into our fort.

We have a geometry class happening before our very eyes! We are looking at two- and three-dimensional shapes and using visualization, spatial reasoning and geometric modeling to solve problems.

These are opportunities that are rich in learning, creativity and team building. We share theories and develop hypotheses about the number of people it might have taken to build the fort, how they got the biggest branches up so high and how they created a base to stabilize the entire structure. We also examine the bottoms of the branches and hypothesize that they were probably broken off during a storm, rather than cut cleanly with a saw.

        

We know that our forts won’t look like the ones that we’ve encountered. We’ll have to use whatever materials we can find in our own play spaces. But our observations give us a better understanding of the fundamentals of fort and teepee construction. These found structures are the spark of inspiration that we need to design a fort of our own!

It’s time to bring out the assessment chart because this gang is on fire! This playful experience in engineering involves concepts such as angles, inclines, balance and elevation. When we let children learn through play, movement and trial and error, we lay the groundwork for the kind of deep learning that builds new neural connections.

Once the seeds are planted, the children often continue to develop their fort-building skills in our program or in their own backyards.

When the Midwest experienced a rare derecho in August 2020—and every house in our area suddenly had a backyard full of branches—our students immediately began collecting the fallen branches to build forts in their neighborhoods.

They had joined the community-wide fort-building movement!

Notice the similarities? By giving our children long periods of uninterrupted time to play and investigate, we empower them to build their own forts and develop new STEM skills and insights that they will be able to transfer to worksheets when the time is right.

When our students returned to our program this fall, we began napping outdoors on a daily basis. Not surprisingly, when a parent suggested a weekend nap to their child, the child insisted on napping outdoors—in her fort. When children build structures, the joy comes not only from the building but from returning to this place that they have created by themselves, for themselves.

These are the moments when I thank our anonymous community of fort builders for “planting the seeds” of fort building with our young learners. These industrious fort architects may be 12 years old or 90 years old. They may be building these impromptu structures to offer protection from the weather, bring joy to others or simply provide a peaceful place for fellow community members to commune with the natural world.

These lovely forts are gifts of time, hard work and beautiful design that bring science, math and engineering into the lives of our youngest citizens.

Thank you for making so many moments of STEM learning possible through play with the children of our community! You inspire all of us! Thank you! You are truly changing our world!

 

 

 

 

 

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Nest Building is STEM Building https://earlymathcounts.org/nest-building-is-stem-building/ https://earlymathcounts.org/nest-building-is-stem-building/#comments Mon, 01 Mar 2021 12:17:17 +0000 http://earlymathcounts.org/?p=12407 “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 […]]]>

“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.

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Return of the Sand Gardens https://earlymathcounts.org/return-of-the-sand-gardens/ https://earlymathcounts.org/return-of-the-sand-gardens/#comments Wed, 19 Aug 2020 10:36:30 +0000 http://earlymathcounts.org/?p=12878   “I found GOLD!” squeals Laura. Four little friends are quick to join her in the latest gold rush in the sandbox. In the wee hours of the morning, often when the sun is barely above the horizon and the coffee is still being brewed, gold will magically appear in our sandbox. Spray-painted rocks that […]]]>

 

“I found GOLD!” squeals Laura. Four little friends are quick to join her in the latest gold rush in the sandbox. In the wee hours of the morning, often when the sun is barely above the horizon and the coffee is still being brewed, gold will magically appear in our sandbox. Spray-painted rocks that will give our young friends hours of digging, collecting, hoarding and, hopefully, sharing.

Once upon a time back in 1886, the first sand garden was created in the yard of the Children’s Mission on Permenter Street on the North End of Boston. In the late 1800s, sand gardens were viewed as safe places for immigrant children to play in during the summer months while their parents worked in factories. Today, these early sand gardens are often referred to as America’s “first playgrounds.” As we reimagine education during the pandemic, perhaps we should harken back to a simpler time and create sand gardens for our young learners!

A sandbox seems so simple, but it is truly a blank canvas—inviting curiosity and creativity, exploration and investigation. It offers a soothing sensory experience and an opportunity to experience natural textures while experiencing the peace and simple pleasures of sand play. Peer pressure will entice wary friends to strip off their shoes and tentatively join in the fun. Placing a big “Shoe Basket” near your sandbox is essential for your own mental health. It will save you hours of searching for socks and shoes. When we add loose parts to our sand, we create opportunities for counting, collecting and designing. We can explore symmetry and patterns. By adding baking tools, we can explore measurement and estimation. Opportunities abound for vocabulary growth and lessons about location and position.

“Joseph, can you get the trucks to drive under our castle?” The children have been busy building and decorating large mounds of sand. Now they have moved on to cautiously digging out tunnels. Tunnel digging builds engineering knowledge as the children predict, problem-solve and collaborate with friends—all while spending long periods of time engaging in what appears to be play. Are you documenting this? Check those early math and science learning standards off of your list!

We can encourage children to mix sand with water to see how adding water changes the physical properties of the sand. This sand play allows the children to create models of their own making. What they imagine, they can create. They create plans, make observations and experiment with ideas. This is science!

As educators and parents, we often miss the opportunities and possibilities that sand play presents. It took me years to figure out that if I took three minutes to rake the sand and make it more inviting, my effort would be rewarded as more children engaged in hours of deep learning and exploration every single day. Consider preparing your sandbox as essential as prepping any other area of your classroom. If the sandbox is full of leaves, too many loose parts from yesterday’s play or any other undesirables, it won’t be, well…desirable! Make sure your sandbox is inviting, and you will “invite” the children to explore math and science concepts with a soothing blank canvas. Unless, of course, there is a major construction project underway. On those days, I gently place a tarp over the sandbox to protect the project until our pint-sized “construction crew” returns the following morning.

If sand is a new adventure for you, recognize and remove any obstacles early on. One important tip is that you must have a water source nearby to make the sand packable. A garden hose, gallon buckets of water or nearby rain barrels will open up a treasure trove of opportunities that are not possible with dry sand. Shade is another important element to consider. You can create shade with a large umbrella if you do not have a tree to shade your sandbox. Or you can use parachutes from the gym, which can be strategically placed with a little bit of ingenuity to create shade.

I know educators who are allergic to sand in the same way that they are allergic to playdough. Ha! I know who you are! But, in this year of uncertainty, let’s allow our students to enjoy the serenity, sensory pleasures and myriad possibilities of outdoor sand play.

I promise you, it will buy you hours of calm, hands-on learning. If you build it, they will come. Just do it!

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Rock and Roll https://earlymathcounts.org/rock-and-roll/ https://earlymathcounts.org/rock-and-roll/#comments Wed, 18 Nov 2020 00:11:21 +0000 http://earlymathcounts.org/?p=13204   One bright fall morning, I notice that the noise level at Under the Gingko Tree is exceptionally low. A quick glance around reassures me that all of my early learners are safe and accounted for. Then I notice a quiet but intense play buzz happening in our rain garden, so I wander over to […]]]>

 

One bright fall morning, I notice that the noise level at Under the Gingko Tree is exceptionally low. A quick glance around reassures me that all of my early learners are safe and accounted for. Then I notice a quiet but intense play buzz happening in our rain garden, so I wander over to see what has captured the children’s unwavering attention for so long.

“See? We are using the log to make our hill!” Jameson explains to me. 

“We are rolling the rocks down the hill, but our hill has a tunnel!” giggles Noa. 

“They go in and then they roll down!” two-year-old Tariq tells me, trying to keep pace with his older friends.

“This rock is flat on this side. It won’t roll, just like Ricky!” Jameson reminds me. 

The rocks in the rain garden and a hollow log have triggered an idea from another one of our favorite books: Ricky, the Rock That Couldn’t Roll.

Ricky is a flat rock that can’t roll with his friends on their favorite hill. Ricky’s friends help him overcome his challenge and find a way for Ricky to play like everyone else.  

                                         

Suddenly we have piles of rocks that have the same names and characteristics as the rocks in the book. I love it when an idea takes hold and inspires creativity and collaboration as the children begin to plan an activity on their own.

We have a STEM morning unfolding in our outdoor classroom! When the children start using words like “in,” “down,” “over,” “under” and “next to,” they are laying the foundation for geometry. Oh, this is going to be a fun morning! 

As I watch the children design and develop models that represent their ideas, I think to myself, “This is what early math and science learning looks like.” Planning and carrying out simple investigations like this one will make your assessment nightmare seem like a dream. Math and science overlap so much in this morning’s quest for understanding. This is the kind of play that hones children’s problem-solving skills and enables them to meet important early learning milestones.

I see the young friends sorting and classifying piles of rocks—grouping the flat rocks together and then creating another classification for the rocks that will fit into the tunnel. I observe and listen as they demonstrate their comprehension of the sorting and classifying process by comparing and sharing descriptions. When children use words such as “short,” “wide,” “heavy” and “light,” they are using descriptors for measurement. When they are guessing, predicting, classifying and putting rocks in a specific order, they are engaging in early algebra. 

By making predictions, changing designs and collecting data for their next rock, the children are building the foundation for more advanced learning in data analysis and probability in the years to come.

“I think there is something blocking it in there….”  Jameson’s voice trails off as he inspects a rock more closely to see why it didn’t tumble in the way that he had expected. He has observed that the rock is encountering some resistance. This is friction!

This is how we lay the foundation of early science through childhood investigation and teamwork. Today, the children are learning about persistence and problem-solving, propelled by the simple but profound joy of creative play.

Now the children are discussing another STEM concept. “Should we flip the log on its other side or move it to a higher rock?” Jameson asks.

I introduce the vocabulary word for their latest STEM adventure: “elevation.”

“Like an elevator! It goes up to the top of the building!” Jameson declares.

I smile. It’s like throwing seeds into the wind. I never know which ones will land on a rock or take root in a little brain. Either way, this is learning through play. Changing the height (elevation) to get a faster roll is working with speed!

The children are also exhibiting a developing sense of spatial awareness as they work out where and in what direction the log should be placed.

“Maybe if we push it, it will go faster!” Sarah suggests.   

When you are working on those early learning standards, listen to the words that your students are using. When Sarah uses the word “push,” this is a change that leads to an action. The outcome of that action is an effect!

This is scientific investigation in progress. Words like “push,” “pull,” “launch” and “force” are all science action words

Ricky—the rock that started this play—is long forgotten. We have naturally moved on to racing our rocks down the tunnel. I am not sure that any child actually remembers which rock is “theirs,” but they know which rock came in first, second, third and last. These are the vocabulary words that tell us that the children are mastering rudimentary skills in numbers and operations. This is a morning of assessment magic! 

If you have ramps in your classroom, or this is the type of play that sparks your energy, try reading the book, Ricky, the Rock That Couldn’t Roll, aloud to the children. Then place some rocks that roll, along with rocks that don’t roll, in your block area. Observe the investigations that take place and check off some early learning standards of your own!

Happy November, my friends. Stay safe and keep playing!

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

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

SNOW MOLDS

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

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

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

 

ICE AND ICICLES

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

IGLOOS

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

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

HIKING

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

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

  

SLEDDING

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

ANIMAL-TRACK INVESTIGATIONS

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

SNOW SCULPTURES

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

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

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

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The Magical Field of Magnets https://earlymathcounts.org/the-magical-field-of-magnets/ https://earlymathcounts.org/the-magical-field-of-magnets/#comments Fri, 15 Jan 2021 12:23:29 +0000 http://earlymathcounts.org/?p=36563   ” 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. […]]]>

 

” 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!

 

 

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Shadow Play https://earlymathcounts.org/shadow-play/ https://earlymathcounts.org/shadow-play/#comments Mon, 01 Feb 2021 13:50:48 +0000 http://earlymathcounts.org/?p=86697   “Do our shadows look like the monsters in the book?” asks James. I glance over and see James and Noa connecting their shadows by overlapping their arms. When we engage children in outdoor shadow play to support active exploration and discovery, their creativity is endless! James and Noa are playing out their version of […]]]>

 

“Do our shadows look like the monsters in the book?” asks James.

I glance over and see James and Noa connecting their shadows by overlapping their arms. When we engage children in outdoor shadow play to support active exploration and discovery, their creativity is endless!

James and Noa are playing out their version of the book, The Dark, Dark Night by M. Christina Butler. This charming children’s tale follows a frog heading home to his pond after a long winter’s sleep. Along the way, he stops to frolic with his friends Badger, Hedgehog, Rabbit and Mouse. As darkness falls, Frog borrows a lantern from his friend, Mouse, to light the way home.

But, as Frog approaches the reeds at the edge of the pond, he finds himself face to face with a HUGE pond monster with enormous claws. Terrified, Frog hightails it back to his friends. Each friend returns to the pond with Frog—only to flee when the monster reappears. But the friends ultimately realize that the fearsome “pond monster” is not a monster at all—just some scary shadows created by light from the lantern.

Our four- and five-year-old students love this tale. But we had to read The Dark, Dark Night many times before the shadow storyline finally sank in for the younger children in the group. It also took a bit of time and investigation for these younger learners to observe that, when we move, our shadows move too!

When we’re outside, we often engage in body-shadow play with the sun as our light source. Exploring the ways that shadows change as we move our bodies is a great way to get kids engaged and excited about learning. Our road is often closed to traffic during the winter months, and we always take the opportunity to grab tape measures to see how long our shadows are.

I often challenge our friends to see if they can disconnect from their shadows. After a few minutes of contorting our bodies to see if we can separate from our shadows, we decide that we can’t, but that never stops the fun and silliness of trying!

We create math shadow games by calling out different shapes and encouraging the children to do their best to create shadows in these shapes. Movements like standing on one foot, reaching up high to touch the sky and walking on all fours all help children develop body awareness.

Here’s a great way to practice fine-motor skills during shadow play: Use the sun, a projector light or a flashlight to create shadows of tiny hands on a wall. The children can work on finger isolation (e.g. pointing with the index finger, counting out the fingers on their hands and wiggling all of the fingers individually); thumb opposition (e.g. touching the thumb to each finger); and other hand positions to create different types of shadows, an activity that helps build dexterity while laying the foundation for later STEM learning. We also play “Follow the Shadow Leader” and encourage the children to recreate the leader’s shadow by duplicating his or her movements.

Shadow play also helps children develop a rudimentary understanding of cause and effect as they observe what makes a shadow and where the light needs to be to cast a shadow. By moving their shadows around, they can investigate different shapes and sizes.

“Look how dark my shadow is today! Yesterday, we could not see it very well.” Owen is the first to recognize that sunnier days and brighter lights create darker shadows. Observations like Owen’s are often followed by other STEM activities such as creating hypotheses, developing theories and collecting data as the children continue their investigations and deepen their understanding of the nature of light and shadow.

Your students may also notice that their shadows are different sizes at different times of the day. Depending on the amount of sunlight that illuminates our play space, their shadows can be longer, shorter or nonexistent.

You can also show the children how to change the size of a shadow. Move an object closer to a light source and the shadow becomes bigger. Move it away from the light source and the shadow becomes smaller.

Light and shadow play is an amazing way for children to explore their world. If the sun is shining, why not meet your Illinois Early Learning Standards for math and science while playing with shadows. Have fun!

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Finding STEM in Squirming Worms https://earlymathcounts.org/finding-stem-in-squirming-worms/ https://earlymathcounts.org/finding-stem-in-squirming-worms/#comments Thu, 01 Apr 2021 11:49:11 +0000 http://earlymathcounts.org/?p=87918   “AAAAUUUUGHHHHHHH! Worms! Look, look! They are everywhere!” Eleanor is jumping up and down hysterically. Nothing will bring our crew running faster than a good worm sighting! Let the earthworm exploration begin. We love worms! Last spring, we witnessed an unusual natural phenomenon as a mass of earthworms wiggled out of their subterranean homes in […]]]>

 

“AAAAUUUUGHHHHHHH! Worms! Look, look! They are everywhere!” Eleanor is jumping up and down hysterically. Nothing will bring our crew running faster than a good worm sighting!

Let the earthworm exploration begin. We love worms!

Last spring, we witnessed an unusual natural phenomenon as a mass of earthworms wiggled out of their subterranean homes in the soil and squirmed onto our sidewalk.

This weird worm event elicited great joy and excitement from our early learners as they raced over to investigate.

There are a number of names for a large group of earthworms, including a bed, a bunch, a clat or a clew. So if you casually refer to a squirming mass of earthworms as a bunch, you are technically correct!

Why are there so many?  Why are they tangled?  Will they bite me? Where is the worm’s mouth?

The curiosity is flowing faster than the answers. When you see excitement at this level, embrace the moment! Grab a camera and start documenting the Illinois Early Learning Standards that you’ll be meeting today!

Worms can be used to teach length—and we sometimes measure them with tape measures. But this is just one of the ways that worms spark investigation, inquiry and analysis in our outdoor curriculum.

Our love of worms has afforded us days and days of study. In the photo above, you can see collaboration, hypothesizing, theorizing and prediction in action.

This is a group of three-year-old scientific investigators—and their brains are on fire! This is STEM exploration at its most engaging as we measure, count, estimate and subtilize while learning about earth science and life science.

Our students are learning that living things grow and change. They are drawing conclusions from their investigations as they scrutinize the worms’ anatomy and behavior.

This fact-finding mission also fosters a respect for life in all its forms. We try really hard not to hurt our worms. When a two-year-old child engages in hands-on investigations with an earthworm, it doesn’t always end so well for the worm. To protect the worms from overzealous handling, we’ve taught the older children to monitor the well-being of the worms in the hands of their younger peers. This is hands-on learning, coupled with collaboration!

As your early learners explore the world of earthworms, encourage them to ask questions that will guide their investigations. By encouraging them to engage in deeper scientific inquiry, you’ll be setting them up for academic success in the years to come.

“Can I hold it? ” asks two-year-old Alex.

As an older friend passes a worm to Alex, she pulls her hand back a few times before she is ready to receive it.

We offer Alex a glove, but she wants to be like the “big kids” and go gloveless. After we reassure her that the worm has no teeth or pincers, she tries again. This is a good example of the importance of time and patience as we guide children through the investigative process.

People often ask how we “get” our kids to hold a worm. We read a lot of books about worms and I make sure that there are worm books on our shelves from March through October. We also observe worms for long periods of time. If our early learners have one brave friend who is willing to pick up a worm, that’s all it takes to persuade the others to persevere, despite their initial trepidation.

As the children engage in their hands-on worm investigations, we throw out facts, often in whispered voices: “Did you know that worms do not have teeth? Worms also do not have pincers or stingers. They have no eyes, legs or arms. They will never hurt us.”

These are the facts that I share with young learners who are anxious or experiencing worms for the first time. A child who investigated worms as a two-year-old last fall may not have retained that memory as a three-year-old—and we may need to reintroduce worms this spring.

Retention and problem-solving skills continue to evolve as students seek answers to their questions through active investigation. Last fall’s observer may be this spring’s hands-on investigator. Our students need long periods of time to observe and learn as this curriculum unfolds in front of their eyes.

By creating an environment that leads to discovery, you are setting your curriculum in motion. Add large rocks, tree cookies or even soil-filled planters that can serve as worm habitats. Some teachers add soil and worms to their sand and water tables to create worm farms in their classrooms. Our goal is to foster the development of inquisitive minds.

We extend our learning with songs and finger-play. We enjoy “Eat Like a Worm Day” as we snack on vegetables such as carrots, cucumbers, lettuce and apples. We make “worms” out of clay—some thick, some thin, some short and some very, very long.

Mr. Nicky's Science Project

Mr. Nicky (pictured above) has a wonderfully funny song titled “Earthworm,” that has taught our children so much about the vital role that worms play in keeping our soil healthy. There are many silly worm songs, but this has a great hook and gets our children moving as they learn new facts about worms while having fun. It’s one of our favorites.

We always try to return worms to their natural habitat when our observations are over. We thank the worms for doing their part to make our lawn healthy and beautiful as we release them back into the place where we found them. We send them home to their families, which resonates with our young learners.

We wish you many happy STEM adventures as you and your early learners study these champions of the soil.

Happy worm hunting!

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STEM in the Bird Feeder https://earlymathcounts.org/stem-in-the-bird-feeder/ https://earlymathcounts.org/stem-in-the-bird-feeder/#comments Wed, 10 Feb 2021 13:36:53 +0000 http://earlymathcounts.org/?p=91868

“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!

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Rainbows, Sunshine and Superheroes https://earlymathcounts.org/rainbows-sunshine-and-super-heros/ https://earlymathcounts.org/rainbows-sunshine-and-super-heros/#comments Wed, 03 Nov 2021 15:09:19 +0000 http://earlymathcounts.org/?p=106267  

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

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

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

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

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

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

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

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

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

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

Color recognition marks an important developmental milestone.

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

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

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

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

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

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

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

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

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

“What’s an arch?” asks Thali.

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

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

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

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

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

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

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

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

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

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

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

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