Why Millions of Dead Trees in the Sierra May Have Helped Save Water During the Drought
Published on by Water Network Research, Official research team of The Water Network in Academic
Scientists at UC Merced’s Sierra Nevada Research Institute (SNRI), UC Irvine, UC Davis and the USDA Forest Service have enumerated the mechanisms that serve as master regulators of streamflow and drought intensity by studying California’s 2012-15 drought.
Their findings are detailed in a new paper published in Scientific Reports.
Widespread tree mortality in Sierra Nevada forests was an important
mechanism regulating water levels during California's recent drought.
Image source: Pixabay
Researchers used measurements from the Southern Sierra Critical Zone Observatory (CZO) in California’s Kings River Basin to pinpoint four distinct mechanisms responsible for regulating runoff levels during the recent drought. Runoff — water from precipitation, snowmelt and natural reservoirs that feeds into mountain streams and rivers — ultimately supplies much of the state’s water.
“Long-term measurements at the CZO allowed us to understand how the drought affected the amount of water supplied by mountains,” study coauthor and UC Irvine Professor Michael Goulden said. “This understanding is needed to more accurately forecast how future droughts will affect water supplies in California and in mountain headwaters around the world, and to help devise strategies to reduce the impact of drought.”
Two mechanisms — evapotranspiration and warming — decreased runoff levels and intensified the overall effects of the drought.
“Runoff in mountain rivers ultimately reflects the difference between precipitation, which occurs as both rain and snow, and water returned to the atmosphere through evapotranspiration, which is mainly water used by plants plus evaporation from soil,” said Roger Bales, SNRI director and lead author of the new study.
The drought was dominated by evapotranspiration, which varied little from year to year in Sierra Nevada forests, even as precipitation levels declined. As a result, more water was returned to the atmosphere than drained into nearby streams and rivers. This alone led to a 30 percent reduction in springtime runoff. The warming climate only made matters worse.
Temperatures were a full degree Celsius higher than they were the decade prior. This warming resulted in drier, hotter atmospheric conditions favorable to further evapotranspiration. Elevated temperatures ultimately led to an additional 5 percent reduction in runoff.
But the news wasn’t all bad for runoff levels. Scientists also described two processes that actually helped mitigate the drought’s harmful effects.
Local differences in precipitation and evapotranspiration resulted in 10 percent more runoff than might otherwise be expected. Even with rising temperatures, winter evapotranspiration remained low at colder, higher elevations. This meant that upslope meltwater, primarily from high-elevation snowpack, acted as a buffer against downslope declines in runoff.
And scientists identified another mechanism that helped reduce the drought’s overall impact. It was this fourth master regulator that proved most interesting to researchers.
Drought years were characterized by widespread tree mortality — the result of increased wildfire and drought-associated tree dieback. This had the effect of thinning forests, but also reduced forest-associated evapotranspiration, leading to a 15 percent increase in 2016 spring runoff.
“This fourth mechanism is potentially the most important in the southern Sierra Nevada, depending on how long the reduced evapotranspiration is sustained,” Bales said.
Read full article: UC MERCED CNRI
Read paper 'Mechanisms controlling the impact of multi-year drought on mountain hydrology' HERE
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