Changes in snow water storage and hydrologic partitioning in an alpine catchment in the Colorado Front Range

As the climate warms, snow‐dominated regions are increasingly susceptible to precipitation phase changes and earlier snowmelt. In alpine catchments, snowmelt is the majority of runoff, governed by heterogeneous interactions among snowfall, wind, topography and vegetation. The role of the alpine snow...

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Bibliographic Details
Published in:Hydrological processes 2024-07, Vol.38 (7), p.n/a
Main Authors: Hale, Katherine E., Musselman, Keith N., Bjarke, Nels R., Livneh, Ben, Hinckley, Eve‐Lyn S., Molotch, Noah P.
Format: Article
Language:English
Subjects:
alpine catchment
Annual precipitation
Budyko
Catchment area
Catchments
Climate
Climate and vegetation
Climate change
Climate models
Climatic analysis
Climatic conditions
DHSVM
Downstream
Ecological research
Ecosystems
Effective precipitation
Evapotranspiration
Future climates
Headwater catchments
Headwaters
Hydrologic analysis
hydrologic modelling
Hydrologic models
hydrologic partitioning
Hydrology
Mountains
Partitioning
Phase changes
Precipitation
Rainfall
Regional climate models
Regional climates
Runoff
Seasonal variations
Seasonality
Snow
Snow accumulation
Snow storage
snow water storage
Snowdrifts
Snowfall
Snowmelt
Snowpack
Soil water storage
Soil-structure interaction
Stream discharge
Stream flow
surface hydrology
Surface water
Vegetation
Water storage
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Summary:As the climate warms, snow‐dominated regions are increasingly susceptible to precipitation phase changes and earlier snowmelt. In alpine catchments, snowmelt is the majority of runoff, governed by heterogeneous interactions among snowfall, wind, topography and vegetation. The role of the alpine snowpack in delaying the downstream release of accumulated snowfall remains understudied, despite its fundamental role in sustaining lower‐elevation ecosystems and populations. We evaluated fine‐scale changes in the magnitude and duration of alpine snow water storage and release by comparing effective precipitation seasonality to that of surface water inputs using a Snow Storage Index (SSI). We forced the Distributed Hydrology Soil Vegetation Model with historical climate conditions and an end‐of‐century warming signal down‐scaled from a 4‐km regional climate model, to simulate future changes in snow water storage and partitioning of precipitation to runoff and evapotranspiration. The hydrological modelling was conducted on a 2‐m spatial grid to resolve fine scale processes over a 0.6‐km2 headwater catchment within the Niwot Ridge Long‐Term Ecological Research site located in the Rocky Mountains, Colorado, USA. Proportionally more rainfall, reduced snowpack size and extent, and earlier snowmelt occurred in the future scenario with decreased catchment average SSI and thus snow water storing capabilities, with inordinately large decreases occurring in areas of the catchment with reconstructed snowdrifts (−57% average and −100% maximum). Using the Budyko framework to evaluate annual hydrologic partitioning, precipitation inputs to streamflow increased by a maximum 10% in large SSI regions with snowdrifts under warming conditions, signifying a potential buffer for total catchment and annual streamflow loss in a future climate. The fine‐scale analysis of hydrologic sensitivities to warming presented herein are important because climate conditions are expected to further reduce alpine snow water storage, alter hydrologic partitioning, and runoff generation for ecosystems and people living downstream. Spatially distributed percent change in annual average Budyko anomaly between control and warming simulations, and average PETP$$ \frac{\mathrm{P}\mathrm{ET}}{\mathrm{P}} $$ and ETP$$ \frac{\mathrm{ET}}{\mathrm{P}} $$ for all grid cells with a positive Snow Storage Index (SSI) value (purple grid cells) and 0 or negative SSI value (white and tan grid cells) in Budyko space. Th
ISSN:0885-6087
1099-1085
DOI:10.1002/hyp.15206