Mathematical modeling of Elbrus glaciers in the 21st century. Part 2. Forecasting glacier evolution and lake formation under various SSP scenarios

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Abstract

Probable scenarios of future changes in the Elbrus glaciers and associated with them phenomena such as formation of glacial lakes and remaining ice masses buried under the debris cover are considered. The SSP scenarios (SSP1–1.9, SSP1–2.6, SSP2–4.5, SSP3–7.0, SSP5–8.5) were used for of future climate forcing. Glacier dynamics was simulated using the GloGEMflow model, which was improved by including a module of evolving debris cover. According to the prognostic calculations of the surface mass balance of the glaciers, the loss of ice mass on the Elbrus will accelerate until the end of the 2030s, reaching approximately –1.1±0.3 m w. e. yr.–1. The volume of the glacier ice is expected to be reducing almost linearly until about 2040, after which the mass loss rate will slow down. Under the warmest climate change scenarios (SSP5–8.5, SSP3–7.0), almost all of the remaining ice masses in the North Caucasus will be concentrated on Elbrus by the end of the century. At the same time, by 2100 the glaciers of Elbrus themselves will retreat up to 4000 m above sea level and higher. In case of moderate warming (SSP1–1.9, SSP1–2.6) the position of glacier fronts may be stabilized at an altitude of 3600–3700 m. The study concerns also the dynamics of the debris cover, predicting its doubling in area and average thickness of 0.22 m by 2040. Although the effect of the debris cover on the total volume of ice on Elbrus is estimated to be minimal, it can temporarily slow down melting of the frontal parts and areas of dead (remaining) ice. According to our estimates, the retreat of the Elbrus glaciers may result in formation of up to 17 new lakes, of which six may potentially be temporarily dammed by dead (remaining) ice zones (up to 60 m thick for Djikaugenkioz). It is expected that the largest lake may be formed on the Djikaugenkioz plateau, it will be dammed by moraine with ice buried under it in the period from 2035 to 2045 if no sufficiently efficient runoff channels will appear. The approximate time and place of formation of such ice masses near the sites of lake formation, depending on the climatic scenario, are shown in the paper, since it is important from the point of view of the risk of outburst floods in the 21st century. Under moderate warming (scenario SSP1–2.6), up to 8 lakes are likely to be formed at the site of retreating glaciers Ulluchiran, Djikaugenkioz, and Bolshoy Azau. All of them may appear in the first half of the century, regardless of the climatic scenario.

About the authors

T. N. Postnikova

Water Problems Institute of RAS

Author for correspondence.
Email: tasinidze@gmail.com
Russian Federation, Moscow

O. O. Rybak

Water Problems Institute of RAS; Institute of Natural and Technical Systems; Vrije Universiteit Brussel

Email: tasinidze@gmail.com

Earth System Science and Departement Geografie, Vrije Universiteit Brussel

Russian Federation, Moscow; Sevastopol; Brussels, Belgium

A. S. Gubanov

Lomonosov Moscow State University

Email: tasinidze@gmail.com

Department of Geography

Russian Federation, Moscow

H. Zekollarie

Vrije Universiteit Brussel

Email: tasinidze@gmail.com

Department of Water and Climate, Faculty of Engineering

Belgium, Brussels

M. Huss

ETH Zürich; Swiss Federal Institute for Forest, Snow and Landscape Research (WSL); University of Fribourg

Email: tasinidze@gmail.com

ETH Zürich; Swiss Federal Institute for Forest, Snow and Landscape Research (WSL); University of Fribourg

Switzerland, Zürich; Birmensdorf; Fribourg

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