A Comparison of Sedimentary Environments in an Alpine Meadow and the Influence on Groundwater Availability, Applying Near Surface Geophysical Methods.

Meadows are recognized for their value to the ecological, hydrologic, and aesthetic functions of a watershed as they attenuate floods, improve water quality and support herbaceous vegetation, promoting high biodiversity. During the dry summer growing season, Alpine meadow complexes are dependent on timely groundwater distribution of winter precipitation preserved in snowpack, and are therefore highly vulnerable to altered seasonal precipitation patterns. Comprehensive understanding of groundwater flux that supports meadow reaches relies on knowledge of their complex stratigraphic and structural subsurface framework. Hydrogeophysics has emphasized the combination of near surface geophysical techniques to qualitatively define these parameters. Van Norden meadow located in the Donner Summit area west of Lake Tahoe, one of the largest sub-alpine meadows in the Sierra Nevada mountain range of Northern California, provides a natural hydrologic laboratory. Previous field campaigns in 2014 and 2015 collected GPR frequencies of 50, 100, and 270 MHz as well as electrical resistivity profiles to better define the groundwater table, sedimentary, and structural features. Where the previous field campaigns yielded cross-sections characterizing the meadow proper as fluvial, fine grained alluvial plain to coarser stream gravels, positioned over glacial till, the 2016 transects aim to cover the proto meadow, before the anthropogenic creation of a reservoir Lake Van Norden. To facilitate transfer of this area from a local land trust to the Forestry Service, a drain in the dam supporting Lake Van Norden was opened in 2016, greatly reducing the water volume, exposing a significant area of previously inundated land and decades of lakebed sediments that will allow us to ascertain thickness and distribution to the underlying glacial till. Lakebed sediment accounts for differential infiltration rates and as in other meadow sites there are most likely buried channels that influence groundwater introduction into the meadow. Resistivity lines from previous field campaigns will be revisited to track and compare the groundwater response in the upstream meadow reaches to the significant base level change. The GPR grid will be expanded as a first observation that may allow us to calculate changes in groundwater volume over time.