Influence of snowmelt on increasing Arctic river discharge: numerical evaluation

IF 3.5 3区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Progress in Earth and Planetary Science Pub Date : 2024-03-12 DOI:10.1186/s40645-024-00617-y
Hotaek Park, Youngwook Kim, Kazuyoshi Suzuki, Tetsuya Hiyama
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Abstract

Snow is the most important component of the Arctic climatic and hydrological system and is directly vulnerable to climate change. In recent decades, observations have indicated significant decreases in the Arctic snow cover and snowfall rate, whereas water discharge from circumpolar Arctic river basins into the Arctic Ocean has increased. To evaluate the contribution, not well quantified, of snow to the river discharge increase, we conducted sensitivity simulations with surface air temperature and precipitation as climatic treatment variables, combining a land surface model and a distributed discharge model. Variables were treated assuming higher climate variations in the Arctic cold season in 1979–2018. The surface and subsurface runoffs simulated by the land surface model were set as inflows in the discharge model to estimate river discharge. Snowmelt mostly converted to surface runoff, accounting for 73.6% of the anomalous surface runoff increase and inducing the simulated peak discharge in spring and early summer. This relationship was enhanced by the winter precipitation increase. Snow loss induced by higher air temperature contributed to the decrease in the peak and annual discharges, but caused the peak discharge to occur earlier. Additionally, warmer temperature increased the proportion of rainfall in the partitioning of precipitation, causing more subsurface runoff, particularly in autumn and winter. These results provide a first separate evaluation of factors influencing Arctic water discharge, including seasonal hydrographs, and illustrate the influence of climate warming-induced snowfall and rainfall variations on the circumpolar Arctic river discharge.

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融雪对增加北极河流排水量的影响:数值评估
雪是北极气候和水文系统最重要的组成部分,很容易受到气候变化的直接影响。近几十年来,观测结果表明北极地区的积雪覆盖率和降雪率显著下降,而从北极环极河流流域排入北冰洋的水量却有所增加。为了评估积雪对河流排水量增加的贡献,我们结合陆地表面模型和分布式排水模型,以地表气温和降水量作为气候处理变量,进行了敏感性模拟。在处理变量时,假设 1979-2018 年北极寒冷季节的气候变化率较高。地表模型模拟的地表和地下径流被设定为排放模型中的流入量,以估算河流排放量。融雪主要转化为地表径流,占地表径流异常增加量的 73.6%,并诱发春季和初夏的模拟峰值排水量。冬季降水量的增加增强了这种关系。气温升高导致的积雪流失造成了峰值和年径流量的减少,但却使峰值出现得更早。此外,气温升高增加了降水在降水分区中的比例,导致更多的地下径流,尤其是在秋冬季节。这些结果首次对影响北极地区排水量的因素(包括季节水文图)进行了单独评估,并说明了气候变暖引起的降雪和降雨变化对北极环极河流排水量的影响。
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来源期刊
Progress in Earth and Planetary Science
Progress in Earth and Planetary Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
6.50
自引率
5.10%
发文量
59
审稿时长
31 weeks
期刊介绍: Progress in Earth and Planetary Science (PEPS), a peer-reviewed open access e-journal, was launched by the Japan Geoscience Union (JpGU) in 2014. This international journal is devoted to high-quality original articles, reviews and papers with full data attached in the research fields of space and planetary sciences, atmospheric and hydrospheric sciences, human geosciences, solid earth sciences, and biogeosciences. PEPS promotes excellent review articles and welcomes articles with electronic attachments including videos, animations, and large original data files. PEPS also encourages papers with full data attached: papers with full data attached are scientific articles that preserve the full detailed raw research data and metadata which were gathered in their preparation and make these data freely available to the research community for further analysis.
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