Climatic factors affecting Kamchatka glacier recession-Reference-Cited by-同舟云学术

Climatic factors affecting Kamchatka glacier recession

Published:2024-01-04 Issue: Volume: Page:
ISSN:0899-8418
Container-title:International Journal of Climatology
language:en
Short-container-title:Intl Journal of Climatology

Author:

Korneva I. A.¹^ORCID,Toropov P. A.¹²^ORCID,Muraviev A. Ya.¹^ORCID,Aleshina M. A.³^ORCID

Affiliation:

1. Glaciology Department Institute of Geography of the Russian Academy of Sciences Moscow Russia

2. Department of Meteorology and Climatology, Faculty of Geography Moscow State University Moscow Russia

3. Laboratory of Climatology Institute of Geography of the Russian Academy of Sciences Moscow Russia

Abstract

AbstractThe reduction in the area and volume of glaciation in all mountain regions of the Earth has strongly accelerated for the last decades. In this work, we analysed the trends of the main climatic parameters which caused the glacier recession in the Kamchatka Peninsula. It was shown that the glaciers of the northern part of the Sredinny Range decreased by 125 km2 (35.6%) from 1950 to 2016–2017. The average rate of their reduction in the period from 2002 to 2016–2017 (1.45%/year) increased approximately 4.3 times compared to the period 1950–2002 (0.34%/year). The greatest reduction is observed in small glaciers with an area of less than 0.1 km2 and in glaciers with southeastern and southern expositions. On the Kronotsky Peninsula, the glacier area reduction for 1957–2019 was equal to 32.1 km2 (35.6%), and the rates were almost the same in the periods of 1957–2000 (0.61%/year) and 2000–2019 (0.67%/year). According to the data of weather stations and ERA5 reanalysis, it was shown that, in the ablation (summer) period the warming rate was minimal (0.3°C/10 years) and in the accumulation period a significant decrease in precipitation (5%–10%/10 years) was revealed in some areas. At the same time, a significant increase in the radiation balance was revealed in the warm season along with a tendency in downward shortwave radiation increase for the last two decades due to a decrease in cloud amount. These trends are in good agreement with the growth of the geopotential height over the North Pacific during the warm season in the 21st century, and with the growth of velocity divergence in the middle troposphere and the intensification of downward air movements. All this confirms an increase in anticyclone frequency in the warm season, which could be the cause of a radiation balance increase and, consequently, an increase in glacier ablation.

Funder

Russian Science Foundation

Publisher

Wiley

Subject

Atmospheric Science

Link

https://rmets.onlinelibrary.wiley.com/doi/pdf/10.1002/joc.8328

Reference68 articles.

1. A report on climate features on the territory of the Russian Federation in 2021. (2022) Moscow: Russian Federal Service for Hydrometeorology and Environmental Monitoring (Roshydromet) 104 p. [in Russian].

2. Mechanisms of the Early 20th Century Warming in the Arctic

3. Bulygina O.N. Razuvaev V.N.&Aleksandrova T.M.(2014a)Description of daily air temperature and precipitation data at meteorological stations of Russia and Former USSR (TTTR). Certificate of state registration of the database no. 2014620942. Available from:http://meteo.ru/data/162‐temperature‐precipitation#описание‐массива‐данных[Accessed 10th July 2022].

4. Bulygina O.N. Razuvaev V.N.&Aleksandrova T.M.(2014b)Description of the snow data at meteorological stations in Russia and the former USSR. Certificate of state registration of the database no. 2014621201. Available from:http://meteo.ru/data/165-snow-cover#opisanie-massiva-dannyh[Accessed 15th September 2022].

5. Bulygina O.N. Veselov V.M.&Razuvaev V.N.(2014c)Description of the dataset of main meteorological parameters by terms at Russian stations. Certificate of state registration of the database no. 2014620549. Available from:http://meteo.ru/data/163-basic-parameters#описание-массива-данных[Accessed 10th October 2022].