Newly identified climatically and environmentally significant high-latitude dust sources

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Authors

MEINANDER Outi DAGSSON-WALDHAUSEROVA Pavla AMOSOV Pavel ASEYEVA Elena ATKINS Cliff BAKLANOV Alexander BALDO Clarissa BARR Sarah L. BARZYCKA Barbara BENNING Liane G. CVETKOVIC Bojan ENCHILIK Polina FROLOV Denis GASSO Santiago KANDLER Konrad KASIMOV Nikolay KAVAN Jan KING James KOROLEVA Tatyana KRUPSKAYA Viktoria KULMALA Markku KUSIAK Monika LAPPALAINEN Hanna K. LASKA Michal LASNE Jerome LEWANDOWSKI Marek LUKS Bartlomiej MCQUAID James B. MORONI Beatrice MURRAY Benjamin MOEHLER Ottmar NAWROT Adam NICKOVIC Slobodan NEILL Norman T. PEJANOVIC Goran POPOVICHEVA Olga RANJBAR Keyvan ROMANIAS Manolis SAMONOVA Olga SANCHEZ-MARROQUIN Alberto SCHEPANSKI Kerstin SEMENKOV Ivan SHARAPOVA Anna SHEVNINA Elena SHI Zongbo SOFIEV Mikhail THEVENET Frederic THORSTEINSSON Throstur TIMOFEEV Mikhail UMO Nsikanabasi Silas UPPSTU Andreas URUPINA Darya VARGA Gyorgy WERNER Tomasz ARNALDS Olafur VIMIC Ana Vukovic

Year of publication 2022
Type Article in Periodical
Magazine / Source Atmospheric Chemistry and Physics
MU Faculty or unit

Faculty of Science

Citation
web https://acp.copernicus.org/articles/22/11889/2022/
Doi http://dx.doi.org/10.5194/acp-22-11889-2022
Keywords Arctic climate; air quality
Description Dust particles from high latitudes have a potentially large local, regional, and global significance to climate and the environment as short-lived climate forcers, air pollutants, and nutrient sources. Identifying the locations of local dust sources and their emission, transport, and deposition processes is important for understanding the multiple impacts of high-latitude dust (HLD) on the Earth's systems. Here, we identify, describe, and quantify the source intensity (SI) values, which show the potential of soil surfaces for dust emission scaled to values 0 to 1 concerning globally best productive sources, using the Global Sand and Dust Storms Source Base Map (G-SDS-SBM). This includes 64 HLD sources in our collection for the northern (Alaska, Canada, Denmark, Greenland, Iceland, Svalbard, Sweden, and Russia) and southern (Antarctica and Patagonia) high latitudes. Activity from most of these HLD sources shows seasonal character. It is estimated that high-latitude land areas with higher (SI??0.5), very high (SI??0.7), and the highest potential (SI??0.9) for dust emission cover >1?670?000?km2, >560?000?km2, and >240?000?km2, respectively. In the Arctic HLD region (?60°?N), land area with SI??0.5 is 5.5?% (1?035?059?km2), area with SI??0.7 is 2.3?% (440?804?km2), and area with SI??0.9 is 1.1?% (208?701?km2). Minimum SI values in the northern HLD region are about 3 orders of magnitude smaller, indicating that the dust sources of this region greatly depend on weather conditions. Our spatial dust source distribution analysis modeling results showed evidence supporting a northern HLD belt, defined as the area north of 50°?N, with a “transitional HLD-source area” extending at latitudes 50–58°?N in Eurasia and 50–55°?N in Canada and a “cold HLD-source area” including areas north of 60°?N in Eurasia and north of 58°?N in Canada, with currently “no dust source” area between the HLD and low-latitude dust (LLD) dust belt, except for British Columbia. Using the global atmospheric transport model SILAM, we estimated that 1.0?% of the global dust emission originated from the high-latitude regions. About 57?% of the dust deposition in snow- and ice-covered Arctic regions was from HLD sources. In the southern HLD region, soil surface conditions are favorable for dust emission during the whole year. Climate change can cause a decrease in the duration of snow cover, retreat of glaciers, and an increase in drought, heatwave intensity, and frequency, leading to the increasing frequency of topsoil conditions favorable for dust emission, which increases the probability of dust storms. Our study provides a step forward to improve the representation of HLD in models and to monitor, quantify, and assess the environmental and climate significance of HLD.
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