雪反照率反馈增强了内华达山脉中雪杂质引起的辐射强迫。

Snow Albedo Feedbacks Enhance Snow Impurity-Induced Radiative Forcing in the Sierra Nevada.

作者信息

Huang Huilin, Qian Yun, He Cenlin, Bair Edward H, Rittger Karl

机构信息

Pacific Northwest National Laboratory Atmospheric Sciences and Global Change Division Richland WA USA.

Research Applications Laboratory National Center for Atmospheric Research Boulder CO USA.

出版信息

Geophys Res Lett. 2022 Jun 16;49(11):e2022GL098102. doi: 10.1029/2022GL098102. Epub 2022 Jun 3.

DOI:10.1029/2022GL098102

PMID:35859851

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9285762/

Abstract

This study employs a fully coupled meteorology-chemistry-snow model to investigate the impacts of light-absorbing particles (LAPs) on snow darkening in the Sierra Nevada. After comprehensive evaluation with spatially and temporally complete satellite retrievals, the model shows that LAPs in snow reduce snow albedo by 0.013 (0-0.045) in the Sierra Nevada during the ablation season (April-July), producing a midday mean radiative forcing of 4.5 W m which increases to 15-22 W m in July. LAPs in snow accelerate snow aging processes and reduce snow cover fraction, which doubles the albedo change and radiative forcing caused by LAPs. The impurity-induced snow darkening effects decrease snow water equivalent and snow depth by 20 and 70 mm in June in the Sierra Nevada bighorn sheep habitat. The earlier snowmelt reduces root-zone soil water content by 20%, deteriorating the forage productivity and playing a negative role in the survival of bighorn sheep.

摘要

本研究采用一个完全耦合的气象-化学-雪模型，来调查吸光颗粒物（LAPs）对内华达山脉积雪变暗的影响。在用时空完整的卫星反演数据进行全面评估后，该模型显示，在消融季节（4月至7月），内华达山脉积雪中的LAPs使雪反照率降低了0.013（0-0.045），产生了4.5 W/m²的中午平均辐射强迫，到7月时增加到15-22 W/m²。积雪中的LAPs加速了积雪老化过程并减少了积雪覆盖率，这使LAPs导致的反照率变化和辐射强迫增加了一倍。在内华达山脉大角羊栖息地，6月时，杂质引起的积雪变暗效应使雪水当量和积雪深度分别减少了20毫米和70毫米。积雪提前融化使根区土壤含水量降低了20%，降低了草料生产力，并对大角羊的生存产生负面影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0082/9285762/a585dec489aa/GRL-49-0-g002.jpg

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雪反照率反馈增强了内华达山脉中雪杂质引起的辐射强迫。

Snow Albedo Feedbacks Enhance Snow Impurity-Induced Radiative Forcing in the Sierra Nevada.

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