The Texas Computers in Education Association conference just ended and I am on the plane heading home. It is a nice conference, with lots of exhibitors, presenters, and attendees. I am going to infer that Texas loves science, because at my presentation, which had a narrow niche of middle school science, critical thinking, and state standards, I estimate there were 300+ people.  I posted the PowerPoint for this presentation on the last blog.

I also was filmed three times, twice for video blogs and one for a web page.  In all three cases I was discussing the Activity Objects of Adaptive Curriculum. Two of these are already available at District Administration – Product Posts and Scholastic Administrator – The Royal Treatment

 I thank District Administration’s Kurt Dyrli and Scholastic Administrator’s Ken Royal, who did one of the first articles about Adaptive Curriculum after interviewing me about two years ago at FETC. Ken really enjoyed the Activity Object on Francisco Redi, who helped disprove the idea of spontaneous generation. When Ken was a former science teacher he did this science experiment in class, replete with decaying meat and putrid smells. 

It will be interesting to see if the idea of video blogging takes off. I suspect that it will do well as a medium, as long as it has either more attractive or loquacious people than me!

I have the good fortune to be in beautiful Austin, Texas today for the Texas Computer Education Association’s (TCEA) annual convention. Austin is a delightful city, and this conference is huge. In a couple of hours I am going to be doing my presentation “Critical Thinking and TEKS Science Content Via Online Activities.”

I am placing the PowerPoint file here for participants and anyone else interested in this topic. Below are some titles and resources from the presentation. 

Click here to access the PowerPoint. tx-critical-thinking2

The text for the slides is presented below. 

What is Critical Thinking?

Some Elements of Critical Thinking

Design a Satellite

ž  describe types of equipment and transportation needed for space travel. (TEKS: 6.13)

ž  http://www.eduweb.com/portfolio/designsatellite/

The World of Goo

ž  demonstrate basic relationships between force and motion using simple machines including pulleys and levers (TEKS: 7.6)

ž  http://2dboy.com/games.php

Creature Creator

ž  prelude to Spore

ž  Free trial edition

ž  How can students making creatures

—  Develop science content?

—  Develop critical thinking?

—  Or both?

Adaptive Curriculum Activity Objects

ž Dancing with the Bees

—  TEKS 6.12: responses to external stimuli

ž Determining Planet Layers from Seismic Waves

—  TEKS 6.6 identify forces that shape features of the Earth; 7.2: organize, analyze, make inferences, and predict trends from direct and indirect evidence

ž Groundwater

—  TEKS 6.1: make wise choices in the use and conservation of resources;  6.14 groundwater

Using gooey balls, in the “World of Goo,” to make towers and bridges is an engaging way to build conceptual ideas in physics, engineering, and chemistry. The game made by a team of two guys (Kyle Gabler and Ron Carmel) at “2D Boy” won the Innovation Award and Technical Excellence Award at the Independent Games Festival. Goo is available for PCs, Macs, and the Wii. IGN named Goo the best Wii game of the year.  In my house, the free trial download version of Goo won the “Win Over the Skeptical 11 Year-Old Award” for totally engaging my son—who proclaimed, “This is addicting!” My eight-year old son called it “very fun.”

That shows the power of Goo. A game that requires no instructions, but you proceed from level-to-level building things to transport the living goo balls. There is something satisfying about building the goo structures, and something powerful about completing the puzzle at each level. Okay, the goo ball creatures and game remind me a bit of the Zoombinis, and the puzzle contexts are not the greatest, but building the structures to solve the puzzle is intriguing and satisfying. And who wants to waste time learning elaborate storylines when there are goo structures to build?

In my trial of the free on-line sample, I built towers and then bridges. Then my 11-year old son took over, starting anew, and quickly blazed past me to get to build balloon structures to help fight gravity. Neither of us met the minimal goo ball rescue at the “Impale Sticky” level, but fortunately we were able to skip this level when we were left a few balls short.

Building a goo structure is difficult to describe but easy to do. You pull one of the goo balls and separate it from the structure. Two or three white “lines of force” (my term not theirs) appear and when you stop pulling it, the white lines become goo links joining the ball to the previous structure. Of course there is a lot of jiggling and the pull of gravity is evident. If you pull a ball too far away from the others, the lines of force disappear and you realize you need to put it closer.

Science Education and Goo

Linking goo balls forms triangular tresses, which are important units of engineering design. Through trial-and-error learning, we experience that triangle goo formations are easy to build and stable. It is a nice contrast, because it seems in the world of play (from Lincoln Logs™ to Legos™), rectangular formations dominate. The tresses are then used to build towers, bridges, and dangling structures. There is a nice science (and international touch) in the use of metric measurements such a “you have 4.4 meters to go.”

The physics of Goo feels pretty real, and this can be a bridge to many physics concepts. As you build structures, the notions of a good foundation and center of gravity come into play. Build it one way too far, and it falls down; keep the center of gravity above the base, and the tower rises. There is also a sense of harmonics/resonance/vibration in that if your structure starts to bend and bob, you have to be careful that your additions don’t cause more of this in an undesired direction.

At some higher levels of Goo, buoyancy comes into play, along with levers and moments, as balloons lift up lever arms. When this is applied to building a bridge, the balloon placement is critical because too much lift or too little gets the balloons popped. Placing the balloon closer or further from the pivot point can decrease or increase the lift.

For chemistry, the most obvious notion is the idea of adhesion and cohesion. Goo balls being attracted to other goo balls is cohesion. When they stick to something else, like the level where you have to climb up out of a canyon and make them stick to the walls, you have adhesion.

How do you Goo?

If you are teaching an engineering class, I think you have good justification to buy a class set of the “World of Goo.” I also think this would make a great addition to the computers of an elementary school computer lab. I can imagine Mr. Cosgrove (my fifth grade teacher) saying: “After you finish your graphs, if you have time you can Goo.” But for stepping softly into the “World of Goo,” give your students an extra-credit assignment to download the free version (link) at home and complete a certain number of levels. They can use screenshots to prove (and display) their work.

Edu-Goo

Winning awards is great and selling lots of this game must be pretty exciting to the creators. But I think the next endeavor should be an Edu-Goo product line. The possibilities are endless so I will just name three: (a) Online competitions between classes, schools, or the world to see who can build the Goo bridge to support the most weight, (b) three-dimensional Goo structures so students can explore using triangular versus rectangular tresses, (c) DNA Goo, where students can construct DNA double helix molecules. Less exciting but useful are worksheets that can guide exploration and discovery. Edu-Goo could have a teacher contribution page so teachers can contribute ideas about educational uses of Goo. 

As the novelty of PowerPoint presentations in the K-12 classroom fades, the dim lights and streams of text could inspire sleep instead of excitement in science. There are ways that science can be made interesting through PowerPoints. Interactions, great pictures and graphics can really help make a point and share a story.

Fortunately many teachers and people who support education are willing to share their efforts. Here are several powerful sites for science PowerPoint presentations. Of course, with any collections of resources, not all are great so you must browse through and pick and modify. I think combinations of interactive and exciting elements from diverse PowerPoints can make you have a presentation with many strong elements but that is tailored for your students and curriculum. 

Impressive Large Collections

Pete's Science PPTs

Pete’s Science PowerPoints This site has layers and layers of ppt resources.  

World of Teaching: Science  Good PowerPoint presentations that are rated and organized by biology, physics, astronomy, chemistry, and physics.

Science by Jefferson County Schools 

Earth Science and Astronomy and Elementry Science at Nebo School District

Smaller Niche Collections

Chalkbored PPT Title

Powerpoint Physics These present high school level physics PPTs that are animated.

Neuro-Jeopardy - Jeopardy games are a popular review mechanism. This one is on neurobiology. 

Normal Community High School Biology Powerpoints I honestly thought this was a national organization when I saw the layout and the biology PowerPoints. This is a great achievement!

Chalkbored Chemistry Powerpoints These folks show some of the promise in this medium. 

Our Solar System: Tech Learning Center

Resources for Sharing PowerPoints

SlideShare

Assigning Activity Objects and PPTs with Adaptive Curriculum

Adaptive Curriculum. With student subscriptions teachers not only assign great interactive science Activity Objects but they can also assign or provide any online resources. So students can easily access great PowerPoint presentations without remembering complicated addresses. For instance in the picture to the right a lesson plan is being created with the Activity Object “Color Mixing: Paints and Lights” and is combined with two PowerPoint presentations. 

Perhaps the first assay we learned in science class was the starch test, where we dropped iodine on a substance, and if it turned “blue-black”, it indicated the presence of starch.

Now, as modern-day science teachers, we carry on the wisdom of generations of science teachers, and continue to avoid calling the positive result “black and blue”, as no science teacher wants students to associate bruises with white bread or potatoes.

The starch test has become such a common test, that I believe the term “starch test” should replace “litmus test” as the analogy cliché for social or political tests. (For example, Wikipedia states, “A litmus test is a question asked of a potential candidate for high office, the answer to which would determine whether the nominating official would choose to proceed with the appointment or nomination.”) How many non-science teachers even know what litmus is or what a litmus test is? Let’s start using analogies more people can relate to. [People would really start liken that (with an intended pun on the nature of litmus)!]

Today is the six-month anniversary of this blog. It seems such a short time ago, but alas, on June 20, 2008, my first blog was posted. This made me wonder, “How does one know if one is successful after just six short months?

To find the answer to this query, I did a search on blogs. I found no numerical metrics for success. Looking at the latest report from Google Analytics, I did see that more than 35 people per day have read this blog, and that this month alone, there were over 1,000 readers from 70 countries/territories.

The search for blogs about blogs (i.e. metablogs) yielded no numbers, which I viewed once again as evidence that collective wisdom can often be found in groups of people. The qualitative metric I did derive, however, from reading the advice of more experienced blog pundits was this: If a blogger enjoys writing about their interests, and some people are reading, then it should be considered successful. As far as this starch test is concerned, I judge this blog as a success, and I thank you for reading it.

But now on to science teaching and technology, which is the focus of this blog. In the living world, photosynthesis is one of the most important processes. Fortunately, Adaptive Curriculum has a free interactive activity that teachers and students (from all 70 countries/territories) can use to learn more about photosynthesis. In “Plants Needs for Photosynthesis” students conduct several investigations, where they can add or subtract water, light, carbon dioxide, and oxygen. The plant then does its thing (AKA: metabolism) for four hours.

After this, the starch test is performed to see if photosynthesis occurred. In the starch test, the leaves are boiled and then dipped into hot alcohol to remove the green chlorophyll. Next, the leaves are dipped into room temperature water. Finally, drops of iodine are placed upon the leaves. Through these discovery-based learning experiences, students are able to determine the conditions that are needed for photosynthesis to occur.  

Thank you to Adaptive Curriculum for giving us this free Flash-based activity, and for their support of this blog. And no matter what your starch test or litmus test for happiness may be, I wish you a happy holiday season.

Resources:

If you (or your students) don’t know what a litmus test is, here are some links:

Adaptive Curriculum’s “The Properties of Acids”

Adaptive Curriculum’s “The Properties of Bases”

Adler, Kris Lesson Plan: The pH scale. 

Whether at the high school or middle school level, students studying graphs of motion are often confused. One area of confusion occurs in the difference between distance-time graphs and displacement-time graphs. Virtual activities can cause more confusion, unless the right ones are chosen.

Distance-time graphs are a part of many middle school math and science curricula. A Google search for “distance-time graphs” reveals about 10,500 websites with many Java-based and Flash-based online activities. The problem for physics learners and teachers is that in many cases, the developers call their graph a distance-time graph but in reality they are displacement-time graphs.

Here are some examples of (otherwise) good websites making this error:

Moving Man 

Football (soccer) Distance Time Graph

GCSE Bitesize 

There are a few good sites that accurately portray distance-time graphs.

“Crocodile-clips” is a simple, free site where students move a helicopter and create a real-time distance-time graph. It doesn’t matter if the helicopter is moved away from or closer to the starting point. The true distance traveled is displayed on the graph. It is simple but effective.

Commonwealth Curriculum Pack (CCP) is a more involved site. I used this with my mixed age physics class last week and it made the point and kept their interest.

This site uses the context of the 100-meter race to show different arrival speeds. Quickly, my students learned that the steeper the slope (gradient), the greater the speed of the runner. Then we viewed several nice animated sequences of interpolation, which they then interpreted.

PBS Teacher Line http://www.pbs.org/teacherline/resources/activities/race/readings/race.htm.

Students observe stick figures run 400-meter races. They can see the runners move at actual speeds or average speeds, so this serves as a good way to help students understand instantaneous speed versus average speed.

Motion graphs will probably always be confusing for some students. We can reduce confusion with distance-time and displacement-time graphs by using internet resources that accurately portray the difference.

Additional Resources

Adaptive Curriculum’s Activity Object: “Truck On: Position and Velocity-Time Graphs” 

The Physics Classroom Tutorial: Distance and Displacement

Wordle is a tool for displaying words as a graphic image that has implications for science education. The size of the words is a relative indicator of their frequency of use. At the Wordle website I entered the URL for this blog, and received a JAVA-produced image. This image is presented above.

Wordle was developed by Jonathan Feinberg who has produced other science education tools including physics applets and the Secret Lives of Numbers.

Software applications seem to be a creative playground for Feinberg in that he produces what he is interested in and let’s others play with them depending upon their interest. I think Wordle is the most promising classroom tool he has created. But of course, he leaves it to us science educators to explore how to use the tool.

I have just completed 11 days of electricity explorations with a middle school class. I put the text for all my lesson plans into Wordle’s create page and it produced an interesting word art graphic. Teachers will have to take a screen shot of the image to share it with students. (Macintosh: command-shift-4 produces cross-hairs to capture the image, which then appears on your desktop.)

It was interesting to see words such as day, one, and two appear prominently. In checking the word count (see image to left), I realized how often I used the term “one” (apparently it is found in terms such as “someone” as well as pure uses) as I had it over 40 times. These words are not related to electricity, so in MS Word, I deleted (through find and replace) these terms and redid the Wordle image. It is presented below. I will share the image with my students for their review and reaction. It does present an interesting way to view key vocabulary in science. 

I am excited by the potential of Wordle as I stand along the shore. Teachers can make their own “Word Art” or borrow creations of others. There is an ocean of potential waiting to be explored by creative science educators. 

Useful Resources for Electricity and Electricity Science Activities 

• Adaptive Curriculum’s Voltage, Current, and Resistance: Ohm’s Law
• Adaptive Curriculum’s Building Circuits: Light Bulbs in Series
• Circuit Construction Kit

The Circuit Construction Kit (CCK) is a great electricity resource for middle grade and high school students to conduct science investigations and learn about electricity. This FREE resource allows students to produce simple circuits using cells, light bulbs, resistors, and switches. Students can complete series and parallel circuits and they can observe the varying brightness of the light bulbs. CCK also allows students to move into the quantitative realm. Clicking on some additional buttons enables voltmeters and ammeters, and thus measurements of voltage and current can enhance investigations.

Well equipped elementary and middle schools will have batteries, light bulbs, switches, and wires to give students real experiences in constructing circuits. CCK can compliment the physical activities with virtual activities to enhance understanding. Unfortunatley, many schools will not have these physical resources so CCK is a way to help students explore electricity. And, I have not yet come across elementary or middle schools that have class sets of ammeters or voltmeters, so this is a welcome component.

Putting CCK to use

With my middle grade students we are using CCK to discover how to make series and parallel circuits, how to use ammeters and voltmeters, how current and voltage vary in different types of circuits, what are short circuits, and to observe that the ratio voltage/current is equal to resistance (Ohm’s Law).

Of course, the possibilities of how to use CCK are vast. Teacher goals, creativity, and experience level will make this a great resource in some classrooms. Most high school physics teachers will be able to instantly employ this tool. I wish that there were more structured lesson plans for using this tool at the elementary and middle school level so that teachers who are not yet comfortable with electricity could help their students have meaningful experiences. Some lessons can be found at the teaching idea page but these are almost all high school and university lessons.

The diagram above is one of the circuits I asked my middle grade students to construct. Then using a non-contact ammeter, they measured the current through all the branches of the circuit. They later used the voltmeter to measure the voltage across each of the branches.

Reflections in teaching

Working with middle school students, I found that they had few problems in using CCK. We started off constructing real circuits and then reproducing them in CCK where they used the ammeter to measure current at different places in the circuit. Although I know the importance of “free exploration” and wrote about it before in this blog, my regret is that I didn’t allow for free exploration with this virtual tool. Students really wanted to explore lots of things on their own, without me specifying what circuits to create. So, I should have allowed time for this before directing their explorations.

The Circuit Construction Kit is a simple but powerful tool that has a lot of utility in the upper elementary, middle school, and high school classrooms. It is a rich environment for free exploration and it presents many possibilities for guided-inquiry investigations.

Ever since, and probably before, Robert Yager’s (1983) study that suggested the amount of new vocabulary in science textbooks exceeded the number of vocabulary words for learning a foreign language, many educators have been concerned with the number of terms introduced in science classes and methods to help students learn vocabulary.

Recent reforms of state standards, starting with Project 2061, have hopefully reduced the amount of superficial knowledge we ask students to learn. Nevertheless, the new vocabulary can be daunting. The NCLB focus on math and English, with the consequential neglect of science in the elementary grades has resulted in many students entering the middle grades with deficits in their science vocabulary (Cunningham & Allington, 2007).

The teaching of vocabulary is the job of all teachers (Blachowicz & Fisher, 2002). The understanding of content vocabulary is, after all, an excellent predictor of success in the subject area (Wilcox 2006). While inquiry skills, concept development, and understanding are more important goals, students knowing and using key vocabulary are important outcomes of science education.

I recently discovered a tool to assist in vocabulary acquisition. Andrew Sutherland created Quizlet in 2005 when he was a 15 year-old student studying French vocabulary. From what I can tell, it has become a phenomenal success, with over 200,000 registered users. More than flashcards, Quizlet has activities in the following sections: (a) Familiarize, (b) Learn, (c) Test, (d) Play Scatter, and (e) Play Space Race. The great thing about Quizlet is it is all internet based, so there is no need to download and install software, which can be annoying in some situations and impossible in many schools.

Students can type in their own words and definitions and then learn them through a variety of activities. I also like, however, having access to the great repository of already prepared quizlets. For instance, I just taught a unit on magnetism in my son’s middle school classroom. If I would have discovered Quizlet sooner I might have assigned the quizlet on magnets to review for the test. As a parent, my other son (in third grade) had some vocabulary words to learn from his language arts book in the section “Pepita Talks Twice.” A few different quizlets for these words were already established. My son and I reviewed a few words on my iPhone on the way back from soccer practice.  

While we need to be mindful of reducing the “tyranny of terminology” that sometimes describes science courses, we must also help our students learn the key words. Quizlet is a free tool that can help students learn and use scientific vocabulary.

Resources

Adaptive Curriculum, Magnetic Field of  Magnet.  http://www.adaptivecurriculum.com/us/details/USSXP080401

Cunningham, P. M. & Allington, R. L.  (2007). Classrooms that work: They can all read and write. 4th ed. Boston: Allyn and Bacon.

Wilcox, J. (2006). Chicago teachers learn to build academic vocabulary. ASCD Education Update 48 (6): 1–2.

Blachowicz, C., and P. Fisher. 2002. Teaching vocabulary in all classrooms. 2nd ed. Upper Saddle River, NJ: Merrill Prentice- Hall.

Quizlet. http://quizlet.com/

Thelen, J. N. (1984). Improving reading in science.2nd ed. Newark, DE: International Reading Association.

Yager, R. E. (1983). The Importance of Terminology in Teaching K-12 Science. Journal of Research in Science Teaching, 20(6), 577-88. 

In my “Physics for Teachers” class, when student groups present hands-on lessons, they sometimes start with a YouTube video. They are usually well selected and they turn out to be interesting and short. These videos are easy to find and in a university setting easy to display. While some schools have blocked YouTube as a website because of some content, there are workarounds for downloading the videos as .flv files (such as TechCrunch) and playing or converting them with flv players (my favorite for the Macintosh is the free iSquint.

On August 12, 2008, Smartteaching.org posted their 100 top YouTube videos for teachers. Below, I present their science list.

Resources

Adaptive Curriculum’s “Making Sperm and Eggs: Meiosis” Uses Flash-based animations and interactions.