Both of my sons are competitive soccer players. When you live in Phoenix, AZ and you see young athletes running and sweating on a hot day for a prolonged period of time, it is easy to conclude that they would benefit from a beverage with electrolytes and some sugar. The electrolytes replenish the salt that is lost in sweating, and can thus prevent muscle cramping, with the most important ion being potassium. Young competitive soccer players also have very little body fat, so the sugar gives their body energy.

I confess, I went through a Gatorade, PowerAde, and Propel stage for our boys. My oldest son prefers Gatorade, my youngest Propel, and PowerAde was often the least expensive. When I would grocery shop I would always stop on this aisle to see if there were bargains to be had, and then I would stock up. The drinks, made by either Coca-Cola or Pepsi, contain electrolytes and sugar so they seemed to be meeting these basic needs. I like the clearness of the Propel, in that I prefer to not have artificial colors sweating out of the pores of my children (which I never understood why Gatorade thought this was an appealing commercial). Tedd Gorden, of MSU, describes the pros and cons of different formulas for sports drinks.

On hot days with long games or practices, we would send our sons with a large water container and a bottle of a sports drink. Their bodies seemed to tell them what was best, and they always drank far more water than the sports drinks. I have now moved to natural alternatives, so our oldest son is drinking Martinelli apple juice (which he says is the best tasting and comes in a fun round bottle) and our youngest Welch’s grape juice from 10 oz containers. The juices are about the same prices as the 32 oz bottles of sports drinks. So per volume, they cost three times as much, but per outing they are about the same.

If you could design your own sports drink what would it have in it? This intriguing idea is used by Adaptive Curriculum to engage students in the Activity Object “Osmosis.” From this engagement, students examine red blood cells in isotonic, hypertonic, and hypotonic solutions. Then students place raw eggs with the shell removed into different unknown solutions and then label what the solution must be based upon the weight gain or loss in the eggs. The Activity Object has a great engagement with multiple strong interactions. And when it comes to sports drinks, hypotonic solutions are best, whether it is made by Coca-Cola, Pepsi, or grown on a tree.

One of the major themes that runs through many facets of science is the notion of surface area to volume ratio. I remember being a Peace Corps Volunteer in Kenya and using an experimental, guided-inquiry curriculum, inspired by the British Nuffield science program. Students made plasticine cubes of various sizes. I’m not sure why British people have an aversion to clay, but plasticine seems to be their school sculpting material. Then students measured the surface area of the cubes and calculated the volume. Then they calculated the surface area to volume ratio and discover that the larger the object, the smaller the surface area to volume ratio.

Which helps to explain many types of adaptations in biology and why individual cells can’t be the size of houses; they would simply not have enough surface area to absorb the materials they need, like oxygen, or to expel waste. From villi in the intestines to convolutions in the brain, our bodies have many adaptations to increase surface area.

Adaptive Curriculum has a guided inquiry Activity Object called “Surface Area to Volume Ratio in Organisms.” A clever engagement draws the students into the interactive experience. You have a plate of cheese with different size cubes that you are going to put into the microwave. But first, learners predict whether the large cubes or the small cubes will melt first.

Obviously, the small cheese cubes will melt before the larger ones. If you thought this, you have experienced a discrepant event. In actuality, the large cubes melt first. Since the microwave heats from the inside, the smaller cubes lose their heat faster than the large ones. The larger cubes, thus retain more heat and melt faster.  Discrepant events are powerful, because learners want to know why they were wrong.

From this, learners virtually change the size of cubes and see the changes in surface area, volume, and surface area to volume ratio. Then body sizes and shapes of animals are explored, as students learn about the implications of size and shape for heat loss.

My Peace Corps teaching and Adaptive Curriculum are different modes of guided inquiry and discovery learning, but both can help produce deep and life long learning.

Back in 1985 I was fortunate enough to visit George Awad’s New York studio where he was using his architectural skills and space interests to construct a scale model of the universe.  Awad used one million of his own dollars to make this and it was very impressive and enlightening.

This is how Carl Sagan (1997) described it in his book THE DEMON-HAUNTED WORLD: Science as a Candle in the Dark:

Perhaps the grandest museum exhibit can’t be seen. It has no home: George Awad is one of the leading architectural model makers in America, specializing in skyscrapers. He is also a dedicated student of astronomy who has made a spectacular model of the Universe. Starting with a prosaic scene on Earth, and following a scheme proposed by the designers Charles and Ray Eames, he goes progressively by factors of ten to show us the whole Earth, the Solar System, the Milky Way and the Universe. Every astronomical body is meticulously detailed. You can lose yourself in them. It’s one of the best tools I know of to explain the scale and nature of the Universe to children. Isaac Asimov described it as ‘the most imaginative representation of the universe that I have ever seen, or could have conceived of. I could have wandered through it for hours, seeing something new at every turn that I hadn’t observed before.’ Versions of it ought to be available throughout the country – for stirring the imagination, for inspiration and for teaching. But instead, Mr Awad cannot give this exhibit to any major science museum in the country. No one is willing to devote to it the floor space needed. As I write, it still sits forlornly, crated in storage.

In my office, I have the model of the Big Dipper that George Awad gave me during that 1985 visit. After seeing so many 2-dimensional drawings of the big dipper, the model is a 3-dimensional view that shows how relative size and distance influence what we see in the night sky.

Then there was the famous  Powers of Ten Video (or applet) that gave us the broad view of the universe and kept on magnifying by ten, until we arrived in Florida, and then descended into a plant.

Now the folks at Primax Studio have done their own Scale of the Universe with drawn images, instead of partially using photographs, but the music and the interactive aspects make it delightful to explore.  

The scale of the universe is difficult to fully appreciate but we are getting closer due to multimedia tools. A 3-d Imax movie will soon be in theaters.

Today, I am at NSTA in Philadelphia. A great city, and we have been having fabulous weather. My presentation today is on the Standards Based Science Fair. I am posting the PowerPoint for this presentation. NSTA 2010.SBSF

In a semi-darkened classroom at Coronado High School, the recessed computer projector shined down upon a slightly cushioned floor. David Birchfield, politely told me, “We only walk on that after we take our shoes off.” So I quickly jumped off. Ms. Mills and her physics class came in, and the students sat in chairs around the perimeter of the square mat, almost as though they were there for a martial arts exhibition.

Then the physics began. There was a handmade object that when you pushed a button it dropped its bottom. It had reflective tape so the mini-cameras around the room could pick up its motion and transmit it to a computer, which interpreted the data and then created dots on the mat to show the motion of the large object or the separated objects.

A student spun around in a circle and then pushed the button. The bottom sphere dropped and fell away from the object. From the dot pattern it was quite clear, and one student even said it spontaneously: “It moved away at the tangent.” No longer would these students have the misconception that a moving object would still hold the circular force because of its prior motion. Indeed, from Newton’s first law, it was apparent the straight-line motion of the object.

Students took turns trying it. Then to keep them engaged in their free exploration, there were a number of challenges issued, starting with “Let’s aim at Justin.” Then they aimed at a fixed target. Then at a target moving the same direction they were spinning, with a student walking and holding the target, and then at a target moving in the opposite direction.

After the class was over, I tried it as well, this time sans shoes. I have experienced the future, and it is on the floor. There is more power in an experience that is whole body, rather than just fingers on a keyboard or a mouse. Watching the physics class, there is also the learner interactions that make this a potentially powerful learning environment. To be sure, we will see applications like this in museums before it makes it into regular classrooms. Because it can be used with many content areas, some schools might have a SMALLab (Situated Multimedia Arts Learning Lab) for all their teachers to share. And no doubt the 3-D tracking system can be brought to use with interactive white boards, making their use more economical.

My thanks goes to Arizona State University’s David Birchfield, Kelly Phillips, Tatyana Koziupa, Mina Johnson, and Leanna Archambault for letting me experience the future. This will be a tool that will help students overcome misconceptions and experience science in a different way.

When it comes to science supplies, you can be sure that measuring devices such as stop watches, scales, rulers, and graduated cylinders will be useful. There is risk however in purchasing other materials, as you wonder will they work.

It all started well with my Sprout and Grow Window kits that I purchased for my elementary sciencemethods classes. They planted the generous supply of pea plant seeds that the kit provided. And in 5 of the 6 windows we had healthy germination. The plants looked neat growing up out of the thin plastic container housing the roots.

But the window idea paid no dividends. Although it was possible to see some small roots amid the very dark soil, it was disappointing how little you could actually see. I took one of the kits home to care for the plants. About one week after we started the kits, I planted the same pea plants in my home garden. Last week I took pictures of pea plants in the kit and in my garden. Our home telephone is put into each picture for scale.

Garden pea plants with phone at bottom

I know this is not a carefully controlled experiment. Nevertheless, clearly the outdoor garden plants did much better than the window indoor plants. Most people would guess that would be the case, even in a “winter” in Phoenix (where we have so far managed to avoid a seriously deadly frost). But without the benefit of being able to view the roots well, you have to wonder, why would you want to use the Sprout and Grow Window kits? So this review, gives these kits a rating of only 1 out of 4 test tubes. In other words, I don’t recommend that you purchase the product.

But it is nice that the pea plants they supplied grew so well outdoors. I have never grown peas before and I must confess I felt a connection to Gregor Mendel as I saw my plants rise up and flower. I even have pea pods starting to form. I think I will hold off on any genetic crosses for the time being but I think I might be up for a virtual experience at Adaptive Curriculum’s “Mendel’s Experiment.”

From the Activity Object "Mendel's Experiment" by Adaptive Curriculum

One of the many reasons I value living in other cultures, is that when I am removed from my culture, I have greater insight into my culture’s affect on who I am.

There is a fascinating radio show produced by NPR’s “This American Life” that explores the impact of testosterone on us. The first segment is a man who lost the ability to produce testosterone. In those four months he describes his loss of desire, not just the desire that we would suppose, but the desire for anything. To be sure , there was peace in not continually wanting, there was however also a sense of dismay in how much who he was dependant on testosterone.

Image from Adaptive Curriculum's "Human Body Systems"

The second segment was from a man who was born as a woman. Except for the growth of side burns and losing the ability to have a cleansing cry, this man didn’t describe how testosterone injections changed him physically. Perhaps it was assumed that almost everybody knows it can lead to secondary sexual characteristics, including bigger bones, stronger muscles, and a deeper voice. The change he described was on viewing women in a different way, and regrettably not being able to be as close to women any more.

Then in what seems like it could be fodder for afternoon TV, the folks at NPR sent in saliva samples to see who had the most testosterone. There was one group of five males and one group of four females. They all predicted relative levels first. Everybody thought that the woman in the office who made decisive decisions and spoke her mind would have the most testosterone. She even thought so, but hoped she was wrong. They were all right. There were differences in opinion for the males, as they displayed various tendencies, interests, and characteristics. The male who had the least was somewhat dismayed by the results. He said something like this, “I could have accepted this if I worked at ESPN’s Sports Center. But I work at NPR.” Then the “winner,” a balding, muscular, gay man (with almost twice as much testosterone as everybody else) wondered aloud, what is Sports Center? Which the least testosterone man took as another wound—he has more testosterone than me but doesn’t know what Sports Center is! It was a very funny radio moment.

The show ends with a mother reporting on and interviewing her very quiet 15 year-old son. In the process she presents how different her son and daughter are.

In high school biology we talk about hormones in general, and delve lightly into sex hormones. If you want a more interesting assignment (than answer Chapter 4 questions) for mature students, assign them this one-hour broadcast to listen to and ask them to write a one-page reflection. Lots of themes will emerge, and as you read your students’ work, you will have insights into who they are.

The show can be accessed or downloaded for free at: http://www.thisamericanlife.org/Radio_Episode.aspx?sched=1230. It can also be purchased at iTunes for 99 cents.

The videos on television show some of the massive destruction and the human toll of the recent earthquake in Haiti. It is difficult to imagine the suffering of the Haitian people. It is an unfortunate example of the devastation of a magnitude 7 earthquake.

It is natural to wonder why or how. When students are ready, teachers may want to discuss  earthquakes and their causes.

The folks at IRIS have a website with a PowerPoint presentation and Quicktime movie that explain a lot of details associated with this particular earthquake and earthquakes in general. The PowerPoint has excellent pictures of the destruction to buildings, without presenting images of human suffering that would be difficult for some students. The image to the right is taken from the PowerPoint.

IRIS (AKA the Incorporated Research Institutes for Seismology) has lots of resources for learning about earthquakes including SeisMac 2.0 which allows Macintosh computers to become seismographs.

In the quest for Science Literacy, we strive to give students an understanding of natural events before they happen. Adaptive Curriculum has two strong Activity Objects, one is on determining the magnitude of an earthquake and the other is determining the location of the earthquake. The image below is from “Earthquakes: Measuring Magnitude.“

When I was doing my sabbatical at the University of San Carlos (Cebu, Philippines), Ed Van den

Berg (one of the really great guys in science education), would have the undergraduate secondary education science students put on physics and chemistry demonstrations for the local school children. It was a delightful way to give them experience teaching and expose children to the interesting world of science. In the picture, two of my students demonstrate their fire tornado. (See http://www.west.asu.edu/rillero/philippines.htm for more of my photographs from the Philippines.)

In this YouTube video below, a similar program is described called “The Little Shop of Physics.”

Tonight, as I understand it, “After Armadeddon” will air at 8 PM on the History Channel. It does present interesting opportunities for science teachers to talk about student ideas and feelings related to future and past disasterous conditions on Earth. It is part of a week of disasters at the History Channel. Here is a description of the show:

Tuesday, January 05, 2010
After Armageddon: – 08:00-10:00 PM

What have past acts of destruction taught us about what will happen to mankind after the apocalypse? Is it inevitable that disaster will someday strike America on an unprecedented level? How has history prepared us? History’s most dramatic events–Hiroshima, 9/11, Hurricane Katrina and others–are examined and analyzed with hard data gathered from their massive aftereffects. The disappearance of water and food supplies, the effects of deteriorated sanitation and health care on the remaining population, and the increased use of violence as a means of survival–all illustrate how societies have responded and survived.

I have an especially keen interest in this show as my son, Hy Rillero, spent just over two-weeks filming his segment, with many long days of work. I am hoping that much of his vignette survives the editing process for this two-hour special. No matter what happens it was a great experience for Hy to work with Director Stephen Kemp (Raw-TV). In Hy’s section, a respiratory virus has wiped out 80% of the US population and he chronicles his family’s quest to survive.  The photo is of Hy and his film mom and dad.