Dr. Kristen Cecala: Using An Ecosystem Services Approach to Water Resources in Biology 210 at Sewanee: the University of the South

Ecosystems Services Approach to Water Resources Module
I implemented a combination of information from Unit 1 & 2 and activities from Unit 2 in addition to a new module in two 3-hour lab periods. Though ecology as a discipline requires understanding human dimensions, I wished to focus more on human influences on ecology and have time to implement the new module. Students in this upper-level course have already completed a pre-requisite course including a lab observing changes in stream condition through an urban watershed and a lab investigating the nitrogen cycle through a wastewater treatment facility.

Unit 1
Unit 1.1 – I did not use this module because students in this course are already familiar with ecosystem services provided by freshwater systems.

Unit 1.2
I used slides from this module to introduce concepts surrounding what a watershed is and what the major processes are transforming precipitation to runoff.
Instead of having students calculate rainfall-runoff relationships, we visually evaluated the differences in the Big Creek and Rock Creek watershed land-use and rainfall-runoff relationships.

Unit 1.3
I presented slides on the storm hydrograph followed by a short classroom discussion of what specific mechanisms could result in changes in the rainfall-runoff relationship in response to urbanization.
After this discussion, we left the classroom for ~40 minute walk through an adjacent watershed. Throughout the watershed, we discussed all the various factors in the watershed that could contribute to a higher proportion of rainfall leaving the basin as runoff. We also discussed how rainfall retention was important for primary productivity in our ecosystem. This suburban watershed had opportunities to talk about storm drains, erosion, soil compaction and types, forest removal, and channel straightening. In our town, this stream often floods regularly, so we also walked the outline of the floodplain and where it flows over the road during floods. This watershed is also gauged by a colleague, and I hope to incorporate their flow data into the next iteration of this module.

Unit 2
Unit 2.1
I assigned the EPA Stormwater Calculator YouTube video for homework for this lab.
I used the Unit 2.1 Tutorial modified to investigate the watershed visited above.
I provided computers for the students to use because the EPA Stormwater Calculator can only be used on a PC. I also had to troubleshoot the download and installation part for those computers.

Unit 2.2
I adapted the Unit 2.2 exercise to develop recommendations for stormwater management on campus.

Students used the suburban stream visited in lab as the reference condition to test different hypotheses about managing stormwater runoff on campus.

Students were instructed to develop guidelines for stormwater management using the EPA Stormwater Calculator assuming a 20% increase in impervious surfaces. Students were instructed to explore the LID controls to determine which LIDs could be implemented and in what capacity to mitigate the increases in runoff with conversion of 20% of the watershed to impervious surfaces.

Students provided a hypothesis for their exploration of LID controls, plotted a figure of their results and an interpretation of the data. They ultimately provided a recommendation to the town of Sewanee to better manage stormwater runoff with increasing development.

Unit 3 – We did not cover Unit 3 in favor of doing the exercise below.

New Module:
Pre-class summative assessment due on Unit 2 and a formative question about how controls on stormwater runoff may also influence nitrogen runoff.

Short (10 minute) introduction to nitrogen and phosphorus cycles along with human influences on both cycles.

Students in groups of 4 completed a concept map of factors contributing to nitrogen export from watersheds online using Bubbl.us.
Brief introduction to our goals for the lab activity and overview of the two sampled watersheds.

Groups were split in half to collect stream water samples. One half of the class (2 people from each lab group) went to an urban stream to collect samples, and the other half went to a fully forested watershed on campus to collect samples. The group sampling the urban watershed returned to the lab first and began development of standard calibration curves.
Once all lab members returned, they completed development of the standard curve and tested their water samples and a rainwater sample I provided for nitrate. This required them to plot data and develop the equation for a best fit line. From this equation and absorbance of their samples, they back calculated nitrate concentrations of their samples.
Students completed a summative assessment discussing their hypothesis for which watershed would have higher nitrate export and how nitrate export should compare to rainwater. I intended for them to sample nitrate and phosphate, but students ran out of time before completing any phosphate analyses. I would like to find time for these phosphate analyses though to demonstrate one of the fundamental differences between nitrogen and phosphorus cycles.