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Integrating the process of science into your teaching

This workshop explores the importance of teaching the process of science in order to help students better understand and remember scientific concepts. It addresses common misconceptions and provides strategies for incorporating the process of science into teaching. The workshop also covers critical concepts in Earth sciences and discusses misconceptions in textbooks and educational research.

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Integrating the process of science into your teaching

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  1. Integrating the process of science into your teaching • Anne E. Egger • Stanford University • Career Prep Workshop • 30 July 2010

  2. “I would have liked to learn more about what any given day at Jonathan [Payne]'s ‘excavation’ site in China entailed. Would he just stare at rocks for 12 hrs. a day or what else did he do?”

  3. What do I mean by the process of science? • We believe that students who understand how science works will better understand and remember scientific concepts • We also believe we might be able to attract more students into science if they know what it is really like (or at least we won’t drive them away) • Unfortunately, our traditional teaching methods and materials focus on the facts of science, not the process • And yet, we know that students can learn a lot of facts and still hold many misconceptions about the process of science • Effective teaching about the process necessarily involves explicitly addressing those misconceptions and giving students the time and background to develop new conceptions

  4. Critical concepts that are unique to Earth sciences • Geologic time/deep time • Spatial thinking, spatial analysis • Complexity of the Earth system • Scientific basis for major societal issues: energy, climate change, water

  5. Natalie Dee

  6. Step one: Uncover misconceptions

  7. Spock, Chief Science Officer, Enterprise What is wrong with this picture? He knows more than anyone else He betrays no emotion He’s Vulcan Logic always prevails Scary “science station”

  8. In “The Next Generation”, Spock is replaced by Data an android

  9. Misconceptions in the media “But while Raymond-Whish’s intimate acquaintance with cancer may harm her credibility as a dispassionate scientist, it may also propel her to help make startling discoveries where no one else has thought to look.” “On Cancer’s Trail” Florence Williams, High Country News, May 26, 2008 “... Darwin... was hardly even a scientist in the sense that we understand the term - a highly trained specialist whose professional vocabulary is so arcane that he or she can only talk to other scientists.” “Who Was More Important, Lincoln or Darwin?” Malcolm Jones, Newsweek, July 14, 2008

  10. Misconceptions in textbooks • There is one scientific method, and it involves experimentation. • And you must know the question first.

  11. Misconceptions from educational research • “Everything is science.” Moss et al., 2001 - Interviews of five US high school students in an environmental science class • “Technology is really good... so the computer can generate a good interpretation.” Ryder and Leach, 2000 - Paper survey of 731 science students across Europe + 19 interviews • Conceptual models are not an important part of data interpretation. Ryder and Leach, 2000 • Controversy resolves when experiments prove a theory right. Ryder et al., 1999 - Interviews of 11 college students at Leeds involved in final year projects • Scientists may not work alone, but it is unclear how they interact. Ryder et al., 1999 • Many more misconceptions in your handouts...

  12. Step two: Teaching the process • Example 1: Being explicit in a lecture (~200 people) • Example 2: Being explicit in an intro lab (~45 people) • Example 3: Being explicit in an advanced course (~12 people) Address misconceptions Be explicit

  13. Example 1:lecture fromIntroduction to Earth Systems • Learning outcome: • Students will be able to evaluate the information they encounter in the news Let’s give it a try. Hurricanes and global warming articles in Science Daily. Hurricane Katrina, Aug. 28, 2005, Image courtesy NOAA

  14. Global warming and hurricanes h global SST = h hurricane strength

  15. Global warming and hurricanes h global SST ≠ h hurricane strength

  16. Global warming and hurricanes h SST = i hurricane landfall (strength?)

  17. Global warming and hurricanes h SST = i hurricane frequency, h strength

  18. Global warming and hurricanes h SST = h storm frequency (strength?)

  19. Global warming and hurricanes h SST = h hurricane frequency n hurricane strength

  20. Global warming and hurricanes • Strong Storms Linked With Rising Sea Surface Temperatures • Natural Climate Changes Can Intensify Hurricanes More Efficiently Than Global Warming • Warmer Ocean Could Reduce Number Of Atlantic Hurricane Landfalls • Global Warming Has Little Impact In Tropical Storm And Hurricane Numbers, NOAA Reports • NASA Study Links Severe Storm Increases, Global Warming • Hurricane Frequency Is Up But Not Their Strength, Say Researchers What’s the deal?

  21. How would you go about evaluating these apparent contradictions? • (Without becoming an expert in climate science/meteorology/hurricane forecasting.)

  22. Science builds on itself March 16, 2006 • Strong Storms Linked With Rising Sea Surface Temperatures • Natural Climate Changes Can Intensify Hurricanes More Efficiently Than Global Warming • Warmer Ocean Could Reduce Number Of Atlantic Hurricane Landfalls • Global Warming Has Little Impact In Tropical Storm And Hurricane Numbers, NOAA Reports • NASA Study Links Severe Storm Increases, Global Warming • Hurricane Frequency Is Up But Not Their Strength, Say Researchers December 13, 2007 Science in Action! January 25, 2008 May 20, 2008 December 28, 2008 September 23, 2009

  23. Scientific controversy creates progress

  24. Scientists use multiple methods • Strong Storms Linked With Rising Sea Surface Temperatures • Natural Climate Changes Can Intensify Hurricanes More Efficiently Than Global Warming • Warmer Ocean Could Reduce Number Of Atlantic Hurricane Landfalls • Global Warming Has Little Impact In Tropical Storm And Hurricane Numbers, NOAA Reports • NASA Study Links Severe Storm Increases, Global Warming • Hurricane Frequency Is Up But Not Their Strength, Say Researchers correlation modeling observation modeling and simulation observation and correlation statistical assessment of existing data Experimentation?

  25. The most robust ideas in science... • ... are supported by multiple lines of evidence • ... are the product of scientific controversy, vetted and evaluated by the scientific community • ... have been developed and tested and refined over time • ... provide a foundation and framework for new scientific investigations • ... are still subject to modification, refinement

  26. Example 2 from Dynamic Earth: Density, Isostasy, and Topography Learning outcomes:Students will explain why the Earth has a bimodal distribution of topography.Students will describe and utilize the tools and techniques that geoscientists use to study the Earth.

  27. Wood block measurements Height ratio Density ratio

  28. Follow-up questions • Using your equation, calculate the thickness of the crust in the Andes, assuming they are made largely of granite and have an average elevation of 5 km above sea level. • Based on what you now know about crustal thickness and isostasy, sketch what you would expect the crust to look like in an east-west cross-section across South America. Include approximate crustal thicknesses.

  29. In the geosciences, we... • ... use detailed description and observation more frequently than experimentation • ... use analogous materials that work on short timescales • ... take repeated measurements to reduce error • ... share data in order to develop large datasets • ... develop physical and mathematical models to simplify complex systems • ... apply those models to understand new areas

  30. Example 3 from Research Preparation: Reading the Scientific Literature Learning outcome:Students will develop strategies for reading and comprehending scientific journal articles.

  31. Example assignment

  32. In-class discussion • Strategies for reading scientific journal articles • Strategies for using the literature • Using bibliographic tools like EndNote and RefWorks

  33. Follow-up assignment

  34. Integrating the process into your teaching* • Put the process in learning outcomes. • Be explicit - all the time. • Include readings* that emphasize the process. • Use real data. • Assess authentically. What about content?

  35. Resources • Visionlearninghttp://www.visionlearning.com • Readings about aspects of the process of science • Can be combined with content-specific readings • Teaching the Process of Sciencehttp://serc.carleton.edu/sp/library/process_of_science/index.html • The how and why • Activities, readings, and courses

  36. Food for thought • What misconceptions about the process of science (and the process of geoscience) did you personally hold? How were they addressed? How might you address those same misconceptions in your teaching/advising? • What aspects of the process of science are most important to include at different levels, from introductory undergraduate to advanced graduate?

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