ED41C-05:
The use of high-frequency data to engage students in quantitative reasoning and scientific discourse

Thursday, 18 December 2014: 9:00 AM
Catherine O'Reilly1, Thomas Meixner2, Nick Bader3, Cayelan Carey4, Devin Castendyk5, Rebekka Gougis-Darner6, Randy Fuller7, Catherine Gibson8, Jennifer Klug9, David Richardson10 and Janet Stomberg6, (1)Illinois State University, Department of Geography-Geology, Normal, IL, United States, (2)University of Arizona, Tucson, AZ, United States, (3)Whitman College, Walla Walla, WA, United States, (4)Virginia Polytechnic Institute and State University, Blacksburg, VA, United States, (5)SUNY Oneonta, Oneonta, NY, United States, (6)Illinois State University, School of Biological Sciences, Normal, IL, United States, (7)Colgate University, Hamilton, NY, United States, (8)Skidmore College, Saratoga Springs, NY, United States, (9)Fairfield University, Fairfield, CT, United States, (10)SUNY College at New Paltz, New Paltz, NY, United States
Abstract:
Scientists are increasingly using sensor-collected, high-frequency datasets to study environmental processes. To expose undergraduate students to similar experiences, our team has developed six classroom modules that utilize large, long-term, and sensor-based, datasets for science courses designed to: 1) Improve quantitative skills and reasoning; 2) Develop scientific discourse and argumentation; and 3) Increase student engagement in science. A team of ten interdisciplinary faculty from both private and public research universities and undergraduate institutions have developed flexible modules suitable for a variety of undergraduate courses. These modules meet a series of pedagogical goals that include: 1) Developing skills required to manipulate large datasets at different scales to conduct inquiry-based investigations; 2) Developing students’ reasoning about statistical variation; and 3) Fostering desirable conceptions about the nature of environmental science. Six modules on the following topics are being piloted during the 2014-15 and 2015-16 academic years prior to broad dissemination: 1) Temporal stream discharge evaluation using USGS data; 2) Temporal stream nutrient loads and eutrophication risk using USGS and MCM-LTER data; 3) Climate change using NOAA weather and Vostok ice core data; 4) Lake ice-off dates using GLEON data; 5) Thermal dynamics in lakes using GLEON data; and 6) Lake metabolism dynamics using GLEON data.

To assess achievement of the pedagogical goals, we will use pre/post questionnaires and video-recordings of students working on modules. Questionnaires will contain modified items from the Experimental Design Ability Test (Sirum & Humberg 2011), the Views on the Nature of Science questionnaire (Lederman et al. 2001), and a validated instrument to measure students’ ideas about variation (Watson et al. 2003). Information gained from these assessments and recordings will allow us to determine whether our modules are effective at engaging students and increasing their quantitative skills. Feedback will also be used by the faculty to revise the modules before they are posted online for widespread dissemination in 2016. This project is funded by an NSF TUES grant.

Back to: Transformative Innovations in Earth, Oceans, and Atmospheric Science Education for Undergraduates Supported by the NSF Educational Funding Programs, and New Needs and Directions I
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