Atmospheric Circulation Anomalies and Key Physical Processes behind Two Categories of Anomalous Eurasian Spring Snowmelt

IF 3.1 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
Yue Sun, Haishan Chen
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Abstract

Eurasian spring snowmelt plays an important role in the subsequent climate and hydrological cycle, however, the understanding of snowmelt itself and its causes remains insufficient. This study explored the basic characteristics of spring snowmelt in the eastern Europe–western Siberia (EEWS) region by classifying snowmelt anomalies into two categories based on the different factors that dominate spring snowmelt, and then investigated the associated atmospheric circulation anomalies and local physical processes. The first category of anomalous snowmelt (category 1) is controlled by both the initial snow mass and the later snowmelt process, while the second category of anomalous snowmelt (category 2) is mainly linked to the later snowmelt process. Specifically, category 1 is characterized by an anomalous trough in EEWS in winter, where water vapor transported and converged, accompanied by anomalous upward motion, which promotes snowfall and snow accumulation, providing initial conditions conducive to snowmelt. In April, this region is controlled by an anomalous ridge, with significant warm advection anomalies and subsidence promoting surface warming, thereby accelerating snow melting. In contrast, the winter circulation anomalies are insignificant in category 2, while the anomalous ridge in April is stronger than in category 1, accompanied by more intense snowmelt processes. In addition, from the surface energy balance perspective, atmospheric downward sensible heat transport is an important factor influencing the anomalous snowmelt in category 1, while shortwave radiation plays a secondary role. Conversely, the snowmelt in category 2 is dominated by shortwave radiation forcing, but the sensible heat effect is slightly weaker. Eurasian spring snowmelt significantly impacts the subsequent climate and hydrological cycle, but the understanding of snowmelt itself and its causes is still inadequate. The purpose of this study is to explore the monthly evolution of atmospheric circulation associated with anomalous snowmelt and its local physical processes associated by categorizing them based on snowmelt characteristics. Category 1 is jointly affected by winter snow accumulation and later warming, while category 2 is dominated by strong snowmelt process in late spring. These two categories are accompanied by different winter and spring circulation configurations. Our results provide a basis for further investigation of snowmelt precursor signals.
两类欧亚春季异常融雪背后的大气环流异常和关键物理过程
欧亚大陆春季融雪在随后的气候和水文循环中起着重要的作用,但对融雪本身及其成因的认识仍然不足。本文根据影响春季融雪的不同因素,将融雪异常分为两类,探讨了东欧-西西伯利亚地区春季融雪的基本特征,并对相关的大气环流异常和局地物理过程进行了研究。第一类异常融雪(第1类)受初始雪团和后期融雪过程共同控制,第二类异常融雪(第2类)主要受后期融雪过程控制。其中,第1类为冬季EEWS异常槽,水汽输送辐合,伴有异常上升运动,促进降雪和积雪积累,为融雪提供了初始条件。4月,该地区受异常脊控制,明显的暖流异常和下沉促进地表增温,加速融雪。第2类冬季环流异常不明显,4月异常脊比第1类强,伴有更强烈的融雪过程。此外,从地表能量平衡角度看,大气向下感热输送是影响1类异常融雪的重要因素,短波辐射起次要作用。相反,二类融雪以短波辐射强迫为主,感热效应略弱。欧亚大陆春季融雪对随后的气候和水文循环有显著影响,但对融雪本身及其成因的认识仍然不足。本研究的目的是基于融雪特征对异常融雪相关的大气环流及其局地物理过程进行分类,探讨与异常融雪相关的月变化特征。第1类受冬季积雪和后期增温共同影响,第2类受春末强融雪过程主导。这两类都伴随着不同的冬、春环流配置。研究结果为进一步研究融雪前兆信号提供了依据。
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来源期刊
Journal of Hydrometeorology
Journal of Hydrometeorology 地学-气象与大气科学
CiteScore
7.40
自引率
5.30%
发文量
116
审稿时长
4-8 weeks
期刊介绍: The Journal of Hydrometeorology (JHM) (ISSN: 1525-755X; eISSN: 1525-7541) publishes research on modeling, observing, and forecasting processes related to fluxes and storage of water and energy, including interactions with the boundary layer and lower atmosphere, and processes related to precipitation, radiation, and other meteorological inputs.
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