Geotechnology in the Classroom Project
description
Transcript of Geotechnology in the Classroom Project
Geotechnology in the Classroom Project www.ntsg.umt.edu; www.SpatialSci.com
Modeling Climate Change in the ClassroomRachel Loehman1,2, Lisa Blank2, and Jeff Crews2
1Numerical Terradynamic Simulation Group, The University of Montana, Missoula, MT2SpatialSci/GTEC, The University of Montana, Missoula, MT
Advance geospatial skills in science
Contribute to a national model for improving science teaching and student learning using geotechnologies
Foster spatial thinking and spatial literacy
PROJECT GOALS
PROJECT RESOURCES
Earth Observing Systems Education Project
GIS4MT 235 participating schools ESRI site license Introductory GIS training
Spatial Sci/GTEC Program Advanced GIS training Web portal Help desk, on-site visits
Students use the climate data archive from the Center for the Study of Carbon Dioxide and Global Change. This archive:Is composed of data from the Carbon Dioxide Information Analysis Center (CDIAC) and National Climatic Data Center (NCDC)
Contains long-term monthly temperature and precipitation data
Consists of 1221 stations within the conterminous US
http://yosemite.epa.gov/oar/globalwarming.nsf/content/index.html
CLASSROOM LESSON PLAN: Climate change and human health: How do changes in temperature and precipitation influence disease outbreaks?
Students explore relationships between climate change and human health using a long-term, national database of observed temperature and precipitation as well as case information for hantavirus pulmonary syndrome (HPS), a rodent-borne disease. The module uses Montana data as an example, but climate and disease data from other states can be easily substituted. The module can be used to address spatial literacy, GIS implementation, data analysis and modeling, and ecosystem and human systems change, fulfilling a number of national science standards.
Investigation 1: Build a climate database
The Center for the Study of Carbon Dioxide and Global Change contends that there has been no global warming for the past 70 years in spite of the fact that in an analysis of 928 papers on global climate change published in refereed scientific journals between 1993 and 2003 NONE OF THE PAPERS disagreed with the statement that “…there is a scientific consensus on the reality of anthropogenic climate change.” (Oreskes, 2004). However, the website provides an excellent climate database that is easy to access, and use of the site allows teachers to explore scientific debate with their students.
Investigation 2: Model Climate TrendsUsing the data obtained in Investigation 1, students determine the temperature and precipitation trends for their site(s) using simple linear regression techniques. Students can then predict what temperature and precipitation will be in 2050 if the trend continues. The data for 2000 and 2050 are placed into a larger database, which is imported to ArcMap, and Inverse Distance Weighting is used to generate statewide estimates of climate change. Difference maps are generated to explore spatial changes.
? Are there spatial differences in temperature and precipitation across Montana?
? Why? What factors might affect microclimates?? Will changes in precipitation and temperature affect the
distribution of plants and animals in Montana?? How might predicted changes affect human populations
and systems?? What other types of spatial data might provide
information on climate trends and ecosystem effects?? Is climate change happening in Montana? What does
the future look like?
Trends can be compared with those predicted by the EPA for their state. Students can explore questions such as:
Average Temperature Change = 1.66°F 0.66°F Average Precipitation Change = 3.97 in 0.72 in
Investigation 3: Predict Climate Change Effects on Human HealthUsing the temperature and precipitation change maps produced in Investigation 2, students overlay human case information for hantavirus pulmonary syndrome (HPS), a climate-sensitive vector-borne disease. Deer mice, the principal reservoir species for HPS, are sensitive to changes in temperature and precipitation. Predicted climate changes may increase the density and distribution of deer mice, thereby increasing the probability of encounters with infected rodents.