巴伦支海海洋热输送对区域海冰和大气静态稳定性的影响

IF 0.7 Q4 GEOSCIENCES, MULTIDISCIPLINARY

Led i Sneg-Ice and Snow Pub Date : 2019-12-01 DOI:10.15356/2076-6734-2019-4-417

M. Akperov, V. Semenov, I. Mokhov, M. A. Dembitskaya, D. Bokuchava, A. Rinke, W. Dorn

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引用次数: 1

摘要

利用HIRHAM/NAOSIM区域气候模式对北极地区的整体模拟结果，研究了海洋热流入巴伦支海对海冰浓度和大气特征(包括冬季大气静态稳定性)的影响。大气静态稳定性是北极地区极地中气旋时空变化的重要指标。利用1979 - 2016年HIRHAM/NAOSIM区域气候模式集合模拟(RCM)结果进行分析。根据ERA-Interim再分析数据设置了RCM在大气中的初始边界条件和侧向边界条件。对具有相同边界条件和相同北极辐射强迫的10个整体模拟进行了分析。通过改变模型中大洋块的初始积分条件，实现了不同的RCM集成模拟。通过改变模式海洋块体积分的初始条件，可以得到不同的集成模拟实现。采用复合方法分析巴伦支海最大和最小海水流入年份的平均值之差。使用Student's t检验估计结果的统计学显著性(显著性水平p < 0.05)。总的来说，区域气候模式较好地再现了巴伦支海海水和热量流入的季节变化。在巴伦支海，海水的变化与海洋热流入、海冰浓度和表面气温之间有很强的关系。因此，冬季流入巴伦支海的海水增加导致静稳定性降低，从而导致区域气旋活动的变化。静态稳定性的下降在巴伦支海南部和斯瓦尔巴群岛西部最为明显。

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The influence of ocean heat transport in the Barents Sea on the regional sea ice and the atmospheric static stability

The influence of the oceanic heat inflow into the Barents Sea on the sea ice concentration and atmospheric characteristics, including the atmospheric static stability during winter months, is investigated on the basis of the results of ensemble simulations with the regional climate model HIRHAM/NAOSIM for the Arctic. The static stability of the atmosphere is the important indicator of the spatial and temporal variability of polar mesocyclones in the Arctic region. The results of the HIRHAM/NAOSIM regional climate model ensemble simulations (RCM) for the period from 1979 to 2016 were used for the analysis. The initial and lateral boundary conditions for RCM in the atmosphere were set in accordance with the ERA-Interim reanalysis data. An analysis of 10 ensemble simulations with identical boundary conditions and the same radiation forcing for the Arctic was performed. Various realizations of ensemble simulations with RCM were obtained by changing the initial conditions for integrating the oceanic block of the model. Different realizations of ensemble simulations with RCM are obtained by changing the initial conditions of the model oceanic block integration. The composites method was used for the analysis, i.e. the difference between the mean values for years with the maximum and minimum inflow of oceanic water into the Barents Sea. The statistical significance of the results (at a significance level of p < 0.05) was estimated using Student's t-test. In general, the regional climate model reproduces the seasonal changes in the inflow of the oceanic water and heat into the Barents Sea reasonably well. There is a strong relationship between the changes in the oceanic water and ocean heat inflow, sea ice concentration, and surface air temperature in the Barents Sea. Herewith, the increase in the oceanic water inflow into the Barents Sea in winter leads to a decrease in static stability, which contributes to changes in regional cyclonic activity. The decrease of the static stability is most pronounced in the southern part of the Barents Sea and also to the west of Svalbard.

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来源期刊

Led i Sneg-Ice and Snow GEOSCIENCES, MULTIDISCIPLINARY-

CiteScore

1.50

自引率

42.90%

发文量

审稿时长

8 weeks

期刊介绍： The journal was established with the aim of publishing new research results of the Earth cryosphere. Results of works in physics, mechanics, geophysics, and geochemistry of snow and ice are published here together with geographical aspects of the snow-ice phenomena occurrence in their interaction with other components of the environment. The challenge was to discuss the latest results of investigations carried out on Russia’s territory and works performed by Russian investigators together with foreign colleagues. Editorial board works in collaboration with Glaciological Association that is professional community of specialists in glaciology from all republics of the Former Soviet Union which are now new independent states. The journal serves as a platform for the presentation and discussion of new discoveries and results which help to elucidate the state of the Earth’s cryosphere and the characteristics of the evolution of the snow-ice processes and phenomena under the current conditions of rapid climate change.