A Wet-Bulb Temperature-Based Rain-Snow Partitioning Scheme Improves Snowpack Prediction Over the Drier Western United States

Yuan Heng Wang; Patrick Broxton; Yuanhao Fang; Ali Behrangi; Michael Barlage; Xubin Zeng; Guo Yue Niu

doi:10.1029/2019GL085722

A Wet-Bulb Temperature-Based Rain-Snow Partitioning Scheme Improves Snowpack Prediction Over the Drier Western United States

Yuan Heng Wang
, Patrick Broxton
, Yuanhao Fang
, Ali Behrangi
, Michael Barlage
, Xubin Zeng
, Guo Yue Niu

Water Resources Science & Engineering

Research output: Contribution to journal › Article › peer-review

57 Scopus citations

Abstract

Accumulation of snowfall during winter and snowmelt in the subsequent spring or earlier summer provides a dominant water source in alpine regions. Most land surface and hydrological models use near-surface air temperature (T_a) thresholds to partition precipitation into snow and rain, underestimating snowfall over drier regions. We developed a snow-rain partitioning scheme using the wet-bulb temperature (T_w), which is closer to the surface temperature of a falling hydrometeor than T_a. T_w becomes more depressed in drier environments as derived from T_w depression equation using T_a and surface air humidity, resulting in a greater fraction of snowfall. We implemented this new T_w scheme in the Noah-MP land surface model and evaluated the model against a high-quality ground-based snow product over the contiguous United States. The results suggest that the new T_w scheme substantially improves the model skill in simulating snow depth and snow water equivalent over most snow-covered grids, especially the higher and drier continental mountain ranges in the Western United States, while it retains the modeling accuracy over the more humid Eastern United States.

Original language	English
Pages (from-to)	13825-13835
Number of pages	11
Journal	Geophysical Research Letters
Volume	46
Issue number	23
DOIs	https://doi.org/10.1029/2019GL085722
State	Published - Dec 16 2019

Funding

This work is funded by NOAA OAR (NA18OAR4590397), NASA MAP Program (80NSSC17K0352), and the NASA Energy and Water Cycle Study awards (NNH13ZDA001N‐NEWS). The NLDAS‐2 data are available online ( http://www.emc.ncep.noaa.gov/mmb/nldas/ ). The University of Arizona snow data are available at the NSIDC data center (doi: 10.5067/0GGPB220EX6A). The wet‐bulb temperature iterative solution code will be released in future WRF release. We thank Keith Jennings and another anonymous reviewer for their constructive comments that help improve the quality of the paper. This work is funded by NOAA OAR (NA18OAR4590397), NASA MAP Program (80NSSC17K0352), and the NASA Energy and Water Cycle Study awards (NNH13ZDA001N-NEWS). The NLDAS-2 data are available online (http://www.emc.ncep.noaa.gov/mmb/nldas/). The University of Arizona snow data are available at the NSIDC data center (doi: 10.5067/0GGPB220EX6A). The wet-bulb temperature iterative solution code will be released in future WRF release. We thank Keith Jennings and another anonymous reviewer for their constructive comments that help improve the quality of the paper.

Keywords

Noah-MP land surface model
precipitation partitioning
snow water equivalent
wet-bulb temperature

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10.1029/2019GL085722

Cite this

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title = "A Wet-Bulb Temperature-Based Rain-Snow Partitioning Scheme Improves Snowpack Prediction Over the Drier Western United States",

abstract = "Accumulation of snowfall during winter and snowmelt in the subsequent spring or earlier summer provides a dominant water source in alpine regions. Most land surface and hydrological models use near-surface air temperature (Ta) thresholds to partition precipitation into snow and rain, underestimating snowfall over drier regions. We developed a snow-rain partitioning scheme using the wet-bulb temperature (Tw), which is closer to the surface temperature of a falling hydrometeor than Ta. Tw becomes more depressed in drier environments as derived from Tw depression equation using Ta and surface air humidity, resulting in a greater fraction of snowfall. We implemented this new Tw scheme in the Noah-MP land surface model and evaluated the model against a high-quality ground-based snow product over the contiguous United States. The results suggest that the new Tw scheme substantially improves the model skill in simulating snow depth and snow water equivalent over most snow-covered grids, especially the higher and drier continental mountain ranges in the Western United States, while it retains the modeling accuracy over the more humid Eastern United States.",

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A Wet-Bulb Temperature-Based Rain-Snow Partitioning Scheme Improves Snowpack Prediction Over the Drier Western United States

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