Quantifying Hyporheic Flow in Beaver Ponds of Varying Size and Elevation within a High Desert Ecosystem
Academic Level at Time of Presentation
Senior
Major
Aquatic Biology
Minor
NA
List all Project Mentors & Advisor(s)
Dr. Howard Whiteman
Presentation Format
Poster Presentation
Abstract/Description
Mountain desert ecosystems tend to have intermittent surface water flows. Driven by snowpack melt, these low-order streams lose the majority of their water by the late summer months. Since the reintroduction of beavers (Castor canadensis), surface water is able to remain year round due to a beaver dams ability to slow water velocity and impound water. This results in an increase of water retention time which allows for a greater hyporheic zone and surface to ground water interaction. In theory, beaver ponds of larger sizes should have an increased surface to ground water interaction relative to ponds of smaller size. To test this hypothesis and quantify seepage flux in beaver ponds, 18 seepage meters were placed along 6 beaver ponds of differing volume and elevation. Meters were run for 4 weeks during the summer months and 1 week in the fall. Surface to ground water interactions had a positive relationship with pond size. This supports the hypothesis that beaver dams noticeably affect the interaction of surface and ground water in low-order desert streams. Additionally, there was an observed trend for decreasing groundwater infiltration with decreasing elevation. To better understand the seepage meter results, particle size, bulk density/porosity, and organic matter analysis will be conducted on sediment samples taken at each meter. Additional sediment samples were taken along transects within each pond to aid in an overall understanding of a ponds surface to ground water interaction.
Spring Scholars Week 2019 Event
Sigma Xi Poster Competition (Juried)
Quantifying Hyporheic Flow in Beaver Ponds of Varying Size and Elevation within a High Desert Ecosystem
Mountain desert ecosystems tend to have intermittent surface water flows. Driven by snowpack melt, these low-order streams lose the majority of their water by the late summer months. Since the reintroduction of beavers (Castor canadensis), surface water is able to remain year round due to a beaver dams ability to slow water velocity and impound water. This results in an increase of water retention time which allows for a greater hyporheic zone and surface to ground water interaction. In theory, beaver ponds of larger sizes should have an increased surface to ground water interaction relative to ponds of smaller size. To test this hypothesis and quantify seepage flux in beaver ponds, 18 seepage meters were placed along 6 beaver ponds of differing volume and elevation. Meters were run for 4 weeks during the summer months and 1 week in the fall. Surface to ground water interactions had a positive relationship with pond size. This supports the hypothesis that beaver dams noticeably affect the interaction of surface and ground water in low-order desert streams. Additionally, there was an observed trend for decreasing groundwater infiltration with decreasing elevation. To better understand the seepage meter results, particle size, bulk density/porosity, and organic matter analysis will be conducted on sediment samples taken at each meter. Additional sediment samples were taken along transects within each pond to aid in an overall understanding of a ponds surface to ground water interaction.