Saturday, January 28, 2012

Science Research Projects

The "research project." When I was in school, I (vaguely) remember doing research projects which mostly consisted of, "Pick a topic, write a paper, and hope for the best."  Given today's wide-open internet, what should a 21st-century research project look like? Unlimited choice and freedom can be daunting to many students, but overly-rigid parameters can stifle creativity. Somewhere in between is a healthy balance where students can explore a research topic in-depth and express their learning in a variety of creative ways.
Image credit: MorgueFile

Over the years, my biannual research projects have evolved to help students both efficiently leverage the latest resources on the internet and maximize their research potential. The "research paper" I produced umpteen years ago in school pales in comparison to the "power projects" my students create today.

While I believe strongly in giving my students choice in expressing their learning, I have found that completely open-ended choice can lead to less-than-excellent results. Students are more apt to achieve excellence when provided with guidelines, structures, and checkpoints along the way. It's my job to facilitate learning, and the research project provides an opportunity for me to help students really kick it up a notch.

For our ocean research project, I've established the following structures and guidelines:

Essential and Supporting Questions
Rather than instruct students to "pick a topic" at the beginning of the project, we spend time brainstorming and writing both essential and supporting questions. An essential question usually begins with either "why" or "how" and is not something that can be easily answered. Supporting questions usually start with "who/what/when/where," are more factual in nature, and serve as the anchor questions around which students conduct their research and write their final product.

To create these questions, I first have students start writing a stream of questions without stopping to edit or judge the quality of the questions. The goal is to get the ideas flowing. Once students have written 20 to 30 questions, they may then start to edit, sort, and condense these questions until they have one essential research question and a minimum of ten supporting questions. These supporting questions provide the keywords and ideas around which students organize their note system, conduct their research, and assemble their final product—a brochure or a comic book.

Organized Note System
At the beginning of the project, we have a discussion about taking notes efficiently and brainstorm various systems for note-taking, such as index cards, sticky notes, outlines, graphical webs, etc. As part of their project registration (via Google Forms), students must indicate what type of organized note system they will be using for the project, and I periodically check to see that students are using their system.

Primary and Secondary Sources 
Students are expected to use primary and secondary science sources for their research, which includes edited materials in our school library as well as various scientific websites that I have curated. During our initial discussions about the project, we talk extensively about the importance of using primary and secondary science sources, such as NASA Oceanography, NOAA National Ocean Service, Office of Naval Research Oceanography, and sites derived from them. Wikipedia is acceptable, as long as it it used as a starting point only. Blind, open-ended searches using large search engines like Google are discouraged, and use of "anybody can answer this question" websites (like eHow and answers.com) are prohibited.

The key to success here is being an active curator—I set up a web page for our project which provides students links to quality resources, reference materials, tutorials, copyright-respectful clipart, and more. If students use other sites, they must justify their choices; if we decide their choice is a quality resource, it will be added to our list of curated websites.

Structured, Yet Flexible, Format
Our ocean project is the first of two research projects we do in science each year. As such, I am slightly more structured about the written expectations of the project. Students may choose to create a brochure or a comic book, either digitally or on paper. I've narrowed down these choices over the years for a couple of reasons: 
  • Left with open-ended choices, students tend to gravitate toward posters. Unfortunately, I have not been too impressed with the poster format—too often it is nothing more than cut-n-paste pictures and text randomly glued to a poster board (usually at the last minute).
  • Brochures and comic books allow for more creativity from students, but also require more planning and organization. This generally leads to much higher quality.
Bibliography and Picture Credits
As scientists, we must cite the work of others, giving them credit and respecting their copyright. One aspect of this project is the formal use of bibliography and picture credits throughout the project. This can be challenging and frustrating for students who view citations as extra work and who are comfortable (and sometimes complacent) about simply cutting and pasting everything from the internet. So, at the beginning of the project we also have a discussion about the importance of using bibliographies and picture credits in research projects in order to achieve three goals:
  1. provide readers with a mechanism for accessing the same material used by students, so that readers can learn more about the topic,
  2. give credit to the original authors of the research materials, and
  3. respect copyright and honor the creative process.
To help students with their citations, I employ both a Bibliography and Picture Credit Help Guide that I created as well as a wonderful bibliography template that I discovered online years ago. Both these tools (as well as various other digital versions) provide students with the structure to more easily and efficiently document their citations. "Make sure you have a bibliography" is not enough guidance for students.

The Journey Is as Interesting as the Destination
Research projects provide students with the opportunity to pursue their own ideas and interests, and I feel they are a vital part of science education. Open-ended research projects, while allowing for 100% freedom and creativity, tend to be too much for many students; rigid term papers are simply stifling and rather boring. A well-designed research project experience requires that teachers serve as active facilitators during the entire project (somewhat like a tour guide). It is time well spent: the experience becomes focused on asking students what they are learning, rather than struggling to keep them on task.

Saturday, January 21, 2012

There's No Place Like Home(work)

NASA's Hubble Space Telescope
I've been thinking about homework (again), and the futility involved in assigning students traditional homework. Traditional homework is an externally imposed construct—it's something done "to" students, rather than something done "for" students. Traditional homework provides little in the way of intrinsic motivation, and there is no correlation between the quantity of traditional homework and academic success (see Alfie Kohn for more thoughts on homework).

Does that mean homework should be completely eliminated from schools (and life)? No. But we need to be more honest about the purpose and quality of homework — homework should enrich students' lives and support them in their quest to become lifelong learners.

So students and parents, here is your daily/monthly/yearly homework:
  • Go read a book
  • Go plant a tree
  • Go for a walk
  • Go take a picture of the sunset
  • Go enjoy the weather
  • Go look at Jupiter through a telescope
  • Go search for the Moon in the sky
  • Go visit the NASA, or NOAA, or USGS website
  • Go watch Cosmos
  • Go research an interest in more detail
  • Go have a conversation about something you learned today
  • Go pick up trash in your neighborhood
  • Go volunteer
  • Go think about the planet and the universe in which you live
  • Go help somebody who needs you 
  • Go be creative
  • Go use your resources
  • Go ask, "Why?"
  • Go stimulate your brain, feed your curiosity, and exercise your body

Saturday, January 14, 2012

Tracking Ocean Currents

NOAA Global Drifter Program: Drifter Buoy
The task is simple: "Your job is to design and draw a device to track ocean currents."

As we've been studying different aspects of ocean currents — causes, movement, etc. — it's a worthwhile endeavor to think about the instruments used to track ocean currents. A major component of How Science Works includes gathering data, and I think it is important for students to consider the myriad challenges scientists face when tasked to collect a particular type of data, such as ocean currents. I, therefore, ask students to design a device that could track ocean currents and share their design with the class (How Science Works, "publication," "discussion with colleagues," and "feedback and peer review").

The designs are always innovative, creative, thoughtful, and reasonably practical. The best part of this activity is comparing student designs with actual ocean tracking devices used by NOAA and seeing the overlap.

NOAA's Global Drifter Program utilizes drifter buoys to track ocean currents around the world:
"The modern drifter is a high-tech version of the "message in a bottle". It consists of a surface buoy and a subsurface drogue (sea anchor), attached by a long, thin tether. The buoy measures temperature and other properties, and has a transmitter to send the data to passing satellites. The drogue dominates the total area of the instrument and is centered at a depth of 15 meters beneath the sea surface."
Students are delighted to see that many of the ideas they developed in class are actually used in the drifter program. We discuss similarities and differences between their designs and NOAA's drifters to better understand the challenges and limitations involved in measuring ocean currents.

The design activity is followed up with a tracking activity that uses data from NOAA's drifter buoys to track the flow of global ocean currents. Students discover that currents in the Pacific Ocean flow in a giant, clockwise gyre at a fairly slow, but steady rate; in the process, large quantities of heat are redistributed around the planet.

It's easy for a teacher to have students just learn factual information about currents from a textbook, but that's like eating processed junk food—it provides little in the way of long-lasting nutritional value (i.e., shallow learning). US science organizations such as NOAA, NASA, and USGS provide valuable data and information that is perfect for an inquiry-based science classroom. These organizations are the primary sources of science discovery and exploration on planet Earth, and we should be leveraging their expertise in the classroom to engage our students in How Science Really Works.



A sampling of student designs for ocean tracking devices:







Saturday, January 7, 2012

Oceanography Questions

Image Credit: Pics4Learning

I frame our science learning in terms of questions—learning goals, laboratory research questions, daily warm-up questions, one-on-one student conversations, etc. Questions stimulate thinking and conversation; the more questions, the better. I am famously known for never giving students "the right answer," but always asking them that one additional question. Of course, my favorite question is, "Why?"  :)

Throughout the school year, I will share some of the questions we ponder as we engage in the process of science. Here is a sampling of some of the "big idea" questions that I pose during our study of physical oceanography:


Water Cycle
  • How is water distributed on planet Earth?
  • How does water cycle through the Earth system?

Ocean Structure and Composition
  • What are the structures and physical characteristics of Earth's oceans?
  • How far does each ocean zone extend?
  • What are the temperatures like in each ocean zone?
  • How does color change as you descend deeper in the ocean?
  • How far below the surface does light penetrate?
  • How does pressure change with ocean depth?
  • How do scientists create maps of the ocean floor?
  • What is the composition of ocean water?
  • What is the average salinity of the world's oceans?
  • What are the factors that cause changes in salinity?
  • How do scientists measure salinity?
  • What factors affect the density of ocean water?

Ocean Circulation
  • How does density affect ocean circulation?
  • How and why does ocean water circulate?
  • How do scientists measure ocean circulation?
  • What types of ocean waves occur?
  • What are the causes of different types of ocean waves?
  • How do tsunami waves form?
  • How do scientists track tsunami waves and inform the public?
  • How do tidal waves work?



For more information about effective questioning:
Ivan Hannel, Insufficient Questioning, Phi Delta Kappan, Vol. 91, No. 3, November 2009, pp. 65-69. In this article, author Ivan Hannel discusses how highly effective questioning can keep students interested and improve their learning.