Past ‘peak water’ in the North Caucasus: deglaciation drives a reduction in glacial runoff impacting summer river runoff and peak discharges

At the end of the 20th—early twenty-first century, mountain glaciers exhibited the most negative mass balances since the beginning of observations. The hydrological consequence of deglaciation is a rise in glacial runoff until a maximum (‘peak water’) is reached, beyond which runoff decreases as gla...

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Veröffentlicht in:	Climatic change 2020-12, Vol.163 (4), p.2135-2151
Hauptverfasser:	Rets, Ekaterina P., Durmanov, Ivan N., Kireeva, Maria B., Smirnov, Andrew M., Popovnin, Viktor V.
Format:	Artikel
Sprache:	eng
Schlagworte:	Annual variations Atmospheric Sciences Catchment area Climate change Climate Change/Climate Change Impacts Climatic data Deglaciation Discharge Earth and Environmental Science Earth Sciences Flood peak Gauges Glacial drift Glacial runoff Glacier melting Glaciers Glaciohydrology Hydrologic data Hydrologic observations Hydrology Meltwater Mountain glaciers Mountains Reduction River basins River discharge River flow River runoff Rivers Runoff Runoff decrease Snowpack Summer
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description	At the end of the 20th—early twenty-first century, mountain glaciers exhibited the most negative mass balances since the beginning of observations. The hydrological consequence of deglaciation is a rise in glacial runoff until a maximum (‘peak water’) is reached, beyond which runoff decreases as glacier extents are reduced. It is likely that the peak water of glacial runoff has already been passed in the central North Caucasus. River basins with more than 1% glacier cover show consistent decreases in mean monthly discharge in July and August (up to 4–6% per decade during 1945–2018), when glacier meltwater contribution to river runoff is high. Meanwhile, in neighbouring non-glacierised basins, runoff in July and August mostly rose. The runoff in June, when glaciers are typically mostly covered by seasonal snowpack, has increased by 2–9% at most gauges. Hydrological data from the Djankuat alpine research catchment in the central North Caucasus indicate a reduction of glacial runoff contribution in recent decades, as the area reduction of Djankuat glacier and increase in debris cover compensate for the increase in glacier melt. The Djankuat river runoff decreased by 29% in July, 42% in August, and 26% in September in 2007–2020 compared with 1968–1978. The mean annual peak discharge has dropped by 1–5% per decade in the central North Caucasus, and it occurs 1–2 weeks earlier. Possible mechanisms of observed changes are discussed. This study provides the data on climate-related changes in the glacial runoff for a previously not investigated region.
doi_str_mv	10.1007/s10584-020-02931-y
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The Djankuat river runoff decreased by 29% in July, 42% in August, and 26% in September in 2007–2020 compared with 1968–1978. The mean annual peak discharge has dropped by 1–5% per decade in the central North Caucasus, and it occurs 1–2 weeks earlier. Possible mechanisms of observed changes are discussed. 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The hydrological consequence of deglaciation is a rise in glacial runoff until a maximum (‘peak water’) is reached, beyond which runoff decreases as glacier extents are reduced. It is likely that the peak water of glacial runoff has already been passed in the central North Caucasus. River basins with more than 1% glacier cover show consistent decreases in mean monthly discharge in July and August (up to 4–6% per decade during 1945–2018), when glacier meltwater contribution to river runoff is high. Meanwhile, in neighbouring non-glacierised basins, runoff in July and August mostly rose. The runoff in June, when glaciers are typically mostly covered by seasonal snowpack, has increased by 2–9% at most gauges. Hydrological data from the Djankuat alpine research catchment in the central North Caucasus indicate a reduction of glacial runoff contribution in recent decades, as the area reduction of Djankuat glacier and increase in debris cover compensate for the increase in glacier melt. The Djankuat river runoff decreased by 29% in July, 42% in August, and 26% in September in 2007–2020 compared with 1968–1978. The mean annual peak discharge has dropped by 1–5% per decade in the central North Caucasus, and it occurs 1–2 weeks earlier. Possible mechanisms of observed changes are discussed. 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V.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Past ‘peak water’ in the North Caucasus: deglaciation drives a reduction in glacial runoff impacting summer river runoff and peak discharges</atitle><jtitle>Climatic change</jtitle><stitle>Climatic Change</stitle><date>2020-12-01</date><risdate>2020</risdate><volume>163</volume><issue>4</issue><spage>2135</spage><epage>2151</epage><pages>2135-2151</pages><issn>0165-0009</issn><eissn>1573-1480</eissn><abstract>At the end of the 20th—early twenty-first century, mountain glaciers exhibited the most negative mass balances since the beginning of observations. 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subjects	Annual variations Atmospheric Sciences Catchment area Climate change Climate Change/Climate Change Impacts Climatic data Deglaciation Discharge Earth and Environmental Science Earth Sciences Flood peak Gauges Glacial drift Glacial runoff Glacier melting Glaciers Glaciohydrology Hydrologic data Hydrologic observations Hydrology Meltwater Mountain glaciers Mountains Reduction River basins River discharge River flow River runoff Rivers Runoff Runoff decrease Snowpack Summer
title	Past ‘peak water’ in the North Caucasus: deglaciation drives a reduction in glacial runoff impacting summer river runoff and peak discharges
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