Abstract
Abstract. In the Pacific Northwest, USA, the extraordinarily low snowpacks of winters 2013–2014 and 2014–2015 stressed regional water resources and the social-environmental system. We introduce two new approaches to better understand how seasonal snow water storage during these two winters would compare to snow water storage under warmer climate conditions. The first approach calculates a spatial-probabilistic metric representing the likelihood that the snow water storage of 2013–2014 and 2014–2015 would occur under +2 °C perturbed climate conditions. We computed snow water storage (basin-wide and across elevations) and the ratio of snow water equivalent to cumulative precipitation (across elevations) for the McKenzie River basin (3041 km2), a major tributary to the Willamette River in Oregon, USA. We applied these computations to calculate the occurrence probability for similarly low snow water storage under climate warming. Results suggest that, relative to +2 °C conditions, basin-wide snow water storage during winter 2013–2014 would be above average, while that of winter 2014–2015 would be far below average. Snow water storage on 1 April corresponds to a 42 % (2013–2014) and 92 % (2014–2015) probability of being met or exceeded in any given year. The second approach introduces the concept of snow analogs to improve the anticipatory capacity of climate change impacts on snow-derived water resources. The use of a spatial-probabilistic approach and snow analogs provide new methods of assessing basin-wide snow water storage in a non-stationary climate and are readily applicable in other snow-dominated watersheds.
Highlights
In the Pacific Northwest (PNW), USA, mountain snowpacks during the winters of 2013–2014 and 2014–2015 were at or near record lows and well below 50 % of the historic median value (Mote et al, 2016; National Resource Conservation Service, 2014, 2015b)
For several decades the Natural Resources Conservation Service (NRCS) Snowpack Telemetry (SNOTEL) network has provided measurements of snow water equivalent (SWE; the amount of water contained within the snowpack) and meteorological data
On 1 March 2015, 47 % of snow monitoring sites in the Willamette River basin (WRB, 29 730 km2, Fig. 1) registered zero SWE, while snow was still present at higher elevations
Summary
In the Pacific Northwest (PNW), USA, mountain snowpacks during the winters of 2013–2014 and 2014–2015 were at or near record lows and well below 50 % of the historic median value (Mote et al, 2016; National Resource Conservation Service, 2014, 2015b). For several decades the Natural Resources Conservation Service (NRCS) Snowpack Telemetry (SNOTEL) network has provided measurements of snow water equivalent (SWE; the amount of water contained within the snowpack) and meteorological data. These station-based measurements have historically served as a proxy for basinwide snow storage and provide an effective SWE index for estimating streamflow; under a shifting climate these statistical relationships have changed (Montoya et al, 2014). While the concurrent drought in California received substantial attention, the economic and environmental impacts in the PNW were profound
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