Abstract
Recent streamflow declines in the Upper Colorado River Basin raise concerns about the sensitivity of water supply for 40 million people to rising temperatures. Yet, other studies in western US river basins present a paradox: streamflow has not consistently declined with warming and snow loss. A potential explanation for this lack of consistency is warming-induced production of winter runoff when potential evaporative losses are low. This mechanism is more likely in basins at lower elevations or latitudes with relatively warm winter temperatures and intermittent snowpacks. We test whether this accounts for streamflow patterns in nine gaged basins of the Salt River and its tributaries, which is a sub-basin in the Lower Colorado River Basin (LCRB). We develop a basin-scale model that separates snow and rainfall inputs and simulates snow accumulation and melt using temperature, precipitation, and relative humidity. Despite significant warming from 1968–2011 and snow loss in many of the basins, annual and seasonal streamflow did not decline. Between 25% and 50% of annual streamflow is generated in winter (NDJF) when runoff ratios are generally higher and potential evapotranspiration losses are one-third of potential losses in spring (MAMJ). Sub-annual streamflow responses to winter inputs were larger and more efficient than spring and summer responses and their frequencies and magnitudes increased in 1968–2011 compared to 1929–1967. In total, 75% of the largest winter events were associated with atmospheric rivers, which can produce large cool-season streamflow peaks. We conclude that temperature-induced snow loss in this LCRB sub-basin was moderated by enhanced winter hydrological inputs and streamflow production.
Highlights
The water supply of one-sixth of the world’s population is dependent upon snowmelt [1], and this reliance on snow is accentuated in dry regions like the westernUS, where over one-half of total runoff originates from snowmelt [2]
To ensure the analysis focused on response intervals that were relevant to annual water supply, we filtered out all quickflow response intervals (QRIs) where quickflow was less than 1% of mean annual streamflow of each basin
Because more than 80% of annual streamflow is generated in winter and spring seasons, we explored whether contrasting water and energy availability dynamics in these two seasons could explain this apparent paradox
Summary
The water supply of one-sixth of the world’s population is dependent upon snowmelt [1], and this reliance on snow is accentuated in dry regions like the westernUS, where over one-half of total runoff originates from snowmelt [2]. The water supply of one-sixth of the world’s population is dependent upon snowmelt [1], and this reliance on snow is accentuated in dry regions like the western. In the Upper Colorado River Basin (UCBR), which currently supplies water to 40 million people, concerns were recently heightened when warmer temperatures since the 1980s were associated with annual streamflow declines [8,9,10]. Warmer temperatures in spring months may accelerate snow and streamflow loss due to higher rates of vapor loss to sublimation and evapotranspiration [8,15,16], and this negative feedback is likely strongest at high elevations (>3000 m) where streamflow production is heavily dependent upon snowmelt inputs. Warming has been associated with more winter rain (less snow) [17]
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