STEM for Homeschoolers

Graphic tile by E. Keyser, ACTS Geometry student

What is STEM and how is it different from science or math?

"STEM" or "STEM education" are hot topics right now, but they sound like you're into teaching plants or helping flowers.  The name itself is misleading.  STEM stands for science, technology, engineering and math, all lumped together in a handy dandy acronym.  So - not plants, but math and science loosely glued together?  No, that's not quite it either.  With this post I'm going to break down what STEM is and compare one day's science class versus STEM class.

What is STEM?

Although you can find umpteen definitions of STEM around, many agree on the following: STEM education combines multiple subjects together while using student-centered learning techniques.  It is an effort to bridge the gap between what a pure science class teaches (biology) and the skills a biological research scientist uses in a career (knows biology, but also needs to communicate well, design and test, use math to analyze data, and interact with other scientific professionals).  STEM education has a heavy focus on design, student initiative and "soft" skills such as collaboration, innovation and invention.

What's a real example of the difference between a science, math or computer class and a STEM class?

I teach several high school math and science courses at a co-op to homeschoolers, along with STEM classes, so I experience this every week. Here's the rundown of what happened on a recent day.

Physics class: we are studying periodic motion, and begin a unit on spring systems.  Students sit on chairs around a table and listen while I lecture and use the whiteboard.  I have several visuals to illustrate how springs work.  Students seem like they understand, and I prompt them for where they see springs in everyday life.  I do all my usual "teacher-ey" things to keep students engaged.  We do a lab exercise, where students in small groups measure data about springs.  I review what their lab report should look like.  End of class. The next class will continue with periodic motion.

STEM class:  Early in the year student groups brainstormed areas of interest in any STEM field.  One group picked alternative energy, so this day we are studying wind tunnels.  I arrive with a fan, clear containers and lots of tools.  After a brief lecture on how wind tunnels design, student groups spread out on the floor to make their own models. I walk between groups, making sure everyone is collaborating well.  While each group works, we talk about how to make smoke lines, how a mesh can help reduce wind turbulence, and what kind of turbines might work well.  We also brainstorm about where turbines could be placed.  We pack up and groups take their models home to finish. The next class will test our models and smoke lines.

Let's run that back.  Both classes were valuable.  Physics was concept-centered, and I used strategies to engage students including a hands-on lab.  STEM was also concept centered, but those concepts drew from multiple sciences and design work.  Students chose the topic and drove the flow of class, working with their peers the entire class.  Their end product will be a workable wind tunnels to test turbine prototypes, along with enhanced collaboration and design skills.

In coming posts I'll outline some age-specific STEM opportunities and what some barriers to STEM involvement are for homeschoolers.  If you have any experience with STEM and would like to add to the conversation, drop me a line at marycsaville@gmail.com or on twitter at @marycsaville.

Graphics by ACTS Geometry Students.  Produced in Google SketchUp

It's time for a conversation about STEM (science, technology, engineering and math) and homeschoolers, both secular and non-.

Traditional subjects like biology or physics might have homeschoolers using a single subject textbook, digital book, online course or co-op.  STEM is something different - it's an opportunity to combine many scientific, mathematical and technological concepts into an amazing soup.

For example, in my STEM class I begin with a outline of what we'll cover, typically a science concept, technology issue, or description of an engineering career. I lecture - briefly, usually no more than 15-20 minutes - then the fun begins. The students, having received information, immediately split into groups to tackle a challenge based in the lecture concepts. Collaboratively they filter water, separate ingredients, study tsunami waves using a model, devise structures out of crazy supplies, launch marshmallows, and many other things. We debrief the exercise as a class and the students complete a reflective journal entry on what they've experienced.

STEM class ends up being student-driven and highly interactive. The students practice the design cycle, brainstorming techniques, innovation skills, and mostly, how to collaborate well on a group project.  I publish their work on my blog, on YouTube or other digital venues.  Some high schools, like our local public Albemarle High School, have academies or programs that promote STEM. Albemarle has MESA - which stands for Math, Engineering and Science Academy. There are wonderful non-profits around, like Charlottesville's Computers 4 Kids, that mentor low-income students in computing skills while providing them computers at program's end.

The nagging question for me is, what are other homeschoolers doing?  Even better, how can we create a community to help them get involved in collaborative STEM work?  Our county has a large and thriving co-op, but what do you do when that's not an option?  Do you know of homeschool co-ops or home groups that offer STEM classes that I can contact? Many areas also have service learning opportunties, which my older STEM students are doing this year. Is  your local homeschool co-op or family group interested?

 I'd looking to hear and collect knowledge about what homeschoolers do for STEM (science, technology, engineering and math) education.  In the future I hope to blog more on creative ways to engage homeschoolers in STEM, pre-engineering curricula, collaborative work and service learning.

If you are in the field of STEM ed and work with homeschoolers or a parent looking to find resources, comment or find me on twitter @marycsaville.  I've created the twitter hashtag #stemhomeschool to bring resources together.



Every day STEM programs online offer ways for homeschoolers to get involved even if they are living in remote areas.
Some of the links that I've found to be very helpful are:
National Service Learning Clearinghouse
Tells you everything you need to know about service learning and how to begin a project in this excellent, hands on, service based educational model.
PBS Zoom Science
Colorful, engaging site with how-to experiments, engineering challenges, science inquiry and observation.  Geared toward elementary through middle school students.
Discovery Education
With all the quality that Discovery brings to the table, this site has resources for STEM curricular units and lesson plans.  Discovery is also pioneering digital textbooks called "techbooks" for future learning - techbooks would be interactive digital content that updates, educates and inspires.  Plus you'd save the backache from lugging around a huge textbook.

STEM ED for Homeschoolers

Recently my STEM class (offered at a non-profit homeschooling co-op) finished up an interactive multi-lesson unit on alternative energy technology. Each student picked an energy topic, researched it and presented it to the class: we heard about fission, photovoltaic effect, high-speed train function, wind turbines and more. One week students designed paper turbines to see how they could affect rotational speed - see how speedy the "turbines" were in the video! We used a Thames and Kosmos car kit where the car could be powered by solar energy, battery energy, or hydrogen energy. The kit helped us explore electricity including static and current, concepts of voltage and resistance, solar panels and battery circuits. Students were able to tinker with, observe and sketch a one-wheel drive transmission and map how electrons actually move through a circuit, turn a gear, and propel a car. One session had students measuring voltages of batteries with a multimeter and experimenting with how to orient a solar panel to maximize voltage or current.

My favorite part was getting the fuel cell component working - this took a ton of repair on a kit that unfortunately was fragile. Once it was workable, students observed the electrolysis of water using a current to separate water into its component gases oxygen and hydrogen! This separation required electronic current to complete, and we were able to make it work with currents from both batteries OR our solar panel! After the oxygen and hydrogen were formed and stored in small tanks leading to a fuel cell, the students saw how the gases combined back into water, releasing electrons, which powered the car without any other energy source!

Recently, we've spent time each week debriefing service learning group work - what's been accomplished, what goals are coming up, and how best to accomplish those goals. I'm happy to report that all four groups now have meaningful work. The teams and projects are:

• Team 1: Partnering with the non-profit homeschool co-op for a parking lot study, scale model creation, study of people movement through the system, and presentation of findings and graphics to the board. Students have already provided feedback on a short-term solution with a graphic showing new car and pedestrian zones.
• Team 2: Innovation/invention group designing a wind tunnel that models shear forces. Planned use of the tunnel to model a vertical axis wind turbine. Potential for copyright/patent application.
• Team 3: Partnering with Computers 4 Kids to design and teach a short class on Google SketchUp. C4K helps low-income students become technologically literate through project-based lessons and mentoring. Team Hedges may present their course to C4K staff, volunteers, or students.
• Team 4: Partnering with the Culpeper Senior Center to increase technology resources available. Students have already done an assessment of the current computer technology available to seniors. Currently there are no networked computers and only 2 of 4 desktops are functioning. Seniors mostly play games like solitaire, if they use the computers at all. Studying ways to provide internet access to the computers and basic computer skills training to either Senior Center staff or seniors themselves. Training may be in hardware or software.

If anyone else is working in the field of STEM service learning in homeschooling, traditional schools or alterative ed, drop me a line! I'm especially eager to hear how and what other homeschooling co-op classes are doing with STEM.

STEM Service Learning: Homeschoolers Gain Collaborative Skills

For seven years now I've taught at a homeschool co-op while my own kids attend public school, and I attended parochial school for 12 years, so I feel like I've gotten a front-row seat to the best of all worlds. I've heard endless debates about which mode of education is best, with lots of stereotypes and suspicion thrown around. My take? There are excellent aspects to each, and each has its own drawbacks. I'd rather skip the esoteric arguments and move right to being part of a solution. If that sounds OK to you, keep reading. If not, go on and post on a debate website somewhere.

My passion is STEM (science technology engineering and math) education. Key elements of STEM ed include group collaborative skills, innovation, and stem concepts through project-based learning. What better place for homeschoolers, who are traditionally more independent learners, to gain experience than at a co-op with other same-aged students?

Last year my 9th and 10th grade Introduction to Engineering students filtered water, built tiny cantilevers, played with polymers and crafted a Wright Flyer out of recyclables. This year many of those same students are in Engineering 2 and we're starting a new effort. It's called service learning, and it's been on my brain ever since I stumbled upon the National Service Learning Partnership's website .

We're embarking on a 20-24 week project (we're 3 weeks in now) called Capstone. In the Capstone projects, teams of three, four or five students will practice service learning and the design cycle. Service learning is a model where educational concepts and teamwork are put to use in projects for the good of the local community. Service learning can happen in any subject - an example would be creating "reading buddies" where older students practice reading skills by working with younger kids.

In the STEM (science/technology/engineering/math) world service learning can happen by student teams designing computer models for churches, inventing products for animal shelters to make their work easier, creating computer applications to help senior citizens, and many other possibilities. Some of these very ideas were proposed last week by student groups.

Some service learning models are student-led, and this is what I'm striving for. Our four class group leaders volunteered for the leads and are doing an admirable job so far. After assembling teams and brainstorming ideas, teams presented their select ideas for feedback. Criteria for Capstone Project approval include meeting an actual need, having a community partner, teacher approval, and of a scope and level of effort to fit well inside a 20-24 week process.

If you are in the Charlottesville, Virginia area, work with a non-profit or community group that has a project, and are willing to partner with some awesome high-school engineering students, drop me a line! Also, if you are interested in supporting our efforts with a donation, that would be much appreciated and would help offset materials costs.

I'll post updates throughout the year on what we cook up.

The Wright Stuff

Image credit: Jm@n Google 3-D warehouse 2011

What can you do with 200 square feet of corrugated cardboard, 100 feet of cardboard rollers, yards of yarn and Makedo connectors? If you add in over 20 students and 5 hours in the hot sun, you get a half-scale model of the Wright Flyer.


Why? Why would we do such a thing? I'm slightly crazy and the awesome students were actually really happy to do it. We finished up our Intro to Engineering course for the year with a four-week unit on the STEM concepts of recycling - where do plastic bottles, diapers, cardboard and glass come from, and where do they go when we throw them away. To "tangify" the lessons (I'm totally coining that word, meaning to make tangible) we did mini-challenges with Makedo and then brainstormed a LARGE group build using only recyclable materials.

In order to practice the design cycle, smaller student teams imagined projects and pitched them to everyone. Students voted and the winning project was to model the Wright Brothers' first flying machine, the 1903 Wright Flyer.
Working off of a Google SketchUp model of the Flyer (credit: J-m@n) from the 3-D warehouse, we shrunk it to half size and printed multiple views with dimensions. Students brought boxes, tubes, plastic bags and old yard, lots of it.


Although our ultimate goal of constructing such a solid Flyer that we could actually launch it failed, we did manage to put together over 75% of the very complicated airplane. I think each of us knows a ton more about Orville and Wilbur's ingenious design and how to work together on a project. We ran into the same issues that every project has: time overruns, material shortages, weather factors - but there's nothing better than practice to learn how to deal with these in a productive manner and keep progressing to a goal. Excellent work, students - you really did something special.

Use Less by Makedo-ing More, Part 2

Student-made Makedo windmill using plastic cups, styrofoam and connectors - video below

We're continuing to study STEM recycling concepts using Makedo as an activity focus. Last week we studied the life cycle of cardboard and made Makedo creations with reusables, this week we covered glass and made more Makedo-dles.

Teaching this class is like playing one big game of Balderdash. If I had to guess what words like "cullet" and "vitrification" meant I would have guessed, in order, a fish and a wine process. No points for me - want to take a try yourself, just pause before reading on...

Glass is one example of an amorphous solid, which is just a fancypants way of saying it doesn't have structure like a crystal. Glass' primary raw material is sand, or silica (SiO2) which is heated and combined with additives to make different types of glass. (I can't help sharing that when lighting strikes sand the intense heat instantaneously forms lightning glass, or fulgurite - it's like petrified lightning!)

Just like water, when glass turns from a solid into a liquid through heat it's called melting. But glass gets its own awesome word, "vitrification", for the change from liquid back to solid glass. Really, at room temperature glass is as frozen as we would be at -50 Celsius. Next time you look through a pane of glass or at a bottle, see a frozen completely reusable liquid!

Glass can withstand this change back and forth from liquid to solid an unending amount of times, which is why it's so good to recycle. So "cullet" is not a bottom-feeding fish, it's crushed glass that's ready to recycle by adding more raw materials and reheating.

My students' earth-friendly activity was to use Makedo to design an object with recyclable parts that moved on their own in the wind. We ran out of time for all groups to complete a working model, but there was one notable success:

excellent work, Zach and teammates!

If you want to learn more, check out the following links:

Video for how glass is recycled
http://earth911.com/recycling/glass/video-how-glass-gets-recycled/

Listing of everything that is recyclable in the city of Charlottesville, VA
http://www.charlottesville.org/Index.aspx?page=566

Household hazardous waste disposal guide locally
http://rswa.avenue.org/household.htm

Corning Museum of Art's website with tons of fun pictures and explanations:
http://www.cmog.org/dynamic.aspx?id=11886

F2NFVAAD857J

Failure does hurt. It just isn't the end.

Hello students and blog readers - I'm going to write something here, and it's tough but I especially want my students to know that I really mean what I say. Blog readers, you can listen in on the conversation but this is primarily written to my students. I tell them all the time that failure can be the best thing because you can learn so much. I cheer when they put tons of effort into a model that doesn't work, since then they pick up and try again. I remember things the most when they have thwarted me over and over before I get it.

Students, our team was just turned down for the next step in the Lemelson-MIT InvenTeams grant cycle. We spent dozens of hours of creative and thoughtful work to document our potential invention and plan, and I have the highest respect for the teams ultimately chosen by MIT. Students, I am so proud of you, you have come so far in just one year. I'm sure we'll still try to prototype our invention through other funding or grants.

This is the real world - yes, I'm fantastically disappointed but also not crushed - if I add up all the times I "succeed" versus "fail" I'm sure the fails would far outpace the wins. I writing this so you know that how we handle the losses is so key, so clutch - and when it comes down to it even though I'm your teacher I'm still learning, just like you.

Here's to you - great work, and I'm looking forward to next year's application.