Understanding Long‐Term Streamflow Response to Snowfall Change: Insights From a Multivariate Analysis

Understanding Long‐Term Streamflow Response to Snowfall Change: Insights From a Multivariate Analysis

Abstract Ongoing climate change is modifying snow dynamics, further altering streamflow (Q) in cold regions. Despite extensive research over the past decades, the impact of changes in snow on mean annual Q remains debated, and the underlying mechanisms driving these responses are still unclear. In t...

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Bibliographic Details
Main Authors: Ying Hou, Juntai Han, Ross Woods, Yuhan Guo, Yuting Yang
Format: Article
Language:English
Published: Wiley 2025-04-01
Series:Water Resources Research
Subjects:
snowfall fraction
streamflow
budyko framework
mechanistic investigation
Online Access:https://doi.org/10.1029/2024WR038215
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Summary:Abstract Ongoing climate change is modifying snow dynamics, further altering streamflow (Q) in cold regions. Despite extensive research over the past decades, the impact of changes in snow on mean annual Q remains debated, and the underlying mechanisms driving these responses are still unclear. In this study, we employ the Budyko framework to establish multivariate relationships between a Budyko model parameter and several variables, including snowfall fraction (fs), across 931 carefully selected snow‐influenced catchments in the Northern Hemisphere. Our results show that the average elasticity of Q to fs across all catchments is 0.13. However, mean annual Q responses vary among catchments, with 78% of catchments experiencing decreased Q and others exhibiting increased Q with declining fs. These variations are manifested in decreased warm‐season Q and increased cold‐season Q, respectively. Additionally, attribution analysis of Q change highlights a critical role of fs changes as a second‐order control on Q after precipitation. Examining possible mechanisms behind the varying Q responses reveal that the influence of fs on snowmelt intensity and snow season available energy is more pronounced in catchments exhibiting positive Q feedback to fs. In contrast, its impact on rainfall intensity and the asynchrony between available energy and liquid water input is greater in catchments displaying negative Q feedback to fs. Our findings enhance the understanding of Q responses to changing fs and provide valuable insights for water resource management in snow‐influenced regions in a warming climate.
ISSN:0043-1397
1944-7973

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