Modeling the transport of nutrients and sediment loads into Lake Tahoe under projected climatic changes

The outputs from two General Circulation Models (GCMs) with two emissions scenarios were downscaled and bias-corrected to develop regional climate change projections for the Tahoe Basin. For one model—the Geophysical Fluid Dynamics Laboratory or GFDL model—the daily model results were used to drive...

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Bibliographic Details
Published in:Climatic change 2013, Vol.116 (1), p.35-50
Main Authors: Riverson, John, Coats, Robert, Costa-Cabral, Mariza, Dettinger, Michael, Reuter, John, Sahoo, Goloka, Schladow, Geoffrey
Format: Article
Language:English
Subjects:
21st century
Atmospheric Sciences
Base flow
Basins
Climate change
Climate Change/Climate Change Impacts
Earth and Environmental Science
Earth Sciences
Elevation
Emission standards
Emissions
Energy balance
Environmental impact
Evapotranspiration
Fluid dynamics
General circulation models
Greenhouse effect
Greenhouse gases
High flow
Hydrodynamics
Hydrologic models
Hydrology
Lakes
Land use
Mathematical models
Meadows
Nutrients
Parametrization
Precipitation
Projection
Rainfall-runoff relationships
Runoff
Sediment load
Sediments
Snow accumulation
Snowline
Snowmelt
Snowpack
Stream flow
Variables
Water quality
Watersheds
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Summary:The outputs from two General Circulation Models (GCMs) with two emissions scenarios were downscaled and bias-corrected to develop regional climate change projections for the Tahoe Basin. For one model—the Geophysical Fluid Dynamics Laboratory or GFDL model—the daily model results were used to drive a distributed hydrologic model. The watershed model used an energy balance approach for computing evapotranspiration and snowpack dynamics so that the processes remain a function of the climate change projections. For this study, all other aspects of the model (i.e. land use distribution, routing configuration, and parameterization) were held constant to isolate impacts of climate change projections. The results indicate that (1) precipitation falling as rain rather than snow will increase, starting at the current mean snowline, and moving towards higher elevations over time; (2) annual accumulated snowpack will be reduced; (3) snowpack accumulation will start later; and (4) snowmelt will start earlier in the year. Certain changes were masked (or counter-balanced) when summarized as basin-wide averages; however, spatial evaluation added notable resolution. While rainfall runoff increased at higher elevations, a drop in total precipitation volume decreased runoff and fine sediment load from the lower elevation meadow areas and also decreased baseflow and nitrogen loads basin-wide. This finding also highlights the important role that the meadow areas could play as high-flow buffers under climatic change. Because the watershed model accounts for elevation change and variable meteorological patterns, it provided a robust platform for evaluating the impacts of projected climate change on hydrology and water quality.
ISSN:0165-0009
1573-1480
DOI:10.1007/s10584-012-0629-8