Newly identified climatically and environmentally significant high-latitude dust sources

Outi Meinander; Pavla Dagsson-Waldhauserova; Pavel Amosov; Elena Aseyeva; Cliff Atkins; Alexander Baklanov; Clarissa Baldo; Sarah L. Barr; Barbara Barzycka; Liane G. Benning; Bojan Cvetkovic; Polina Enchilik; Denis Frolov; Santiago Gassó; Konrad Kandler; Nikolay Kasimov; Jan Kavan; James King; Tatyana Koroleva; Viktoria Krupskaya; Markku Kulmala; Monika Kusiak; Hanna K. Lappalainen; Michał Laska; Jerome Lasne; Marek Lewandowski; Bartłomiej Luks; James B. Mcquaid; Beatrice Moroni; Benjamin Murray; Ottmar Möhler; Adam Nawrot; Slobodan Nickovic; Norman T. O'neill; Goran Pejanovic; Olga Popovicheva; Keyvan Ranjbar; Manolis Romanias; Olga Samonova; Alberto Sanchez-Marroquin; Kerstin Schepanski; Ivan Semenkov; Anna Sharapova; Elena Shevnina; Zongbo Shi; Mikhail Sofiev; Frédéric Thevenet; Throstur Thorsteinsson; Mikhail Timofeev; Nsikanabasi Silas Umo; Andreas Uppstu; Darya Urupina; György Varga; Tomasz Werner; Olafur Arnalds; Ana Vukovic Vimic

doi:10.5194/acp-22-11889-2022

Newly identified climatically and environmentally significant high-latitude dust sources

Outi Meinander^*, Pavla Dagsson-Waldhauserova, Pavel Amosov, Elena Aseyeva, Cliff Atkins, Alexander Baklanov, Clarissa Baldo, Sarah L. Barr, Barbara Barzycka, Liane G. Benning, Bojan Cvetkovic, Polina Enchilik, Denis Frolov, Santiago Gassó, Konrad Kandler, Nikolay Kasimov, Jan Kavan, James King, Tatyana Koroleva, Viktoria KrupskayaMarkku Kulmala, Monika Kusiak, Hanna K. Lappalainen, Michał Laska, Jerome Lasne, Marek Lewandowski, Bartłomiej Luks, James B. Mcquaid, Beatrice Moroni, Benjamin Murray, Ottmar Möhler, Adam Nawrot, Slobodan Nickovic, Norman T. O'neill, Goran Pejanovic, Olga Popovicheva, Keyvan Ranjbar, Manolis Romanias, Olga Samonova, Alberto Sanchez-Marroquin, Kerstin Schepanski, Ivan Semenkov, Anna Sharapova, Elena Shevnina, Zongbo Shi, Mikhail Sofiev, Frédéric Thevenet, Throstur Thorsteinsson, Mikhail Timofeev, Nsikanabasi Silas Umo, Andreas Uppstu, Darya Urupina, György Varga, Tomasz Werner, Olafur Arnalds, Ana Vukovic Vimic

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

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Abstract

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 >1670000 km2, >560000 km2, and >240000 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.

Original language	English
Pages (from-to)	11889-11930
Number of pages	42
Journal	Atmospheric Chemistry and Physics
Volume	22
Issue number	17
DOIs	https://doi.org/10.5194/acp-22-11889-2022
Publication status	Published - 14 Sept 2022

Bibliographical note

Funding Information:
This research was supported by the Ministry for Foreign Affairs of Finland (IBA project no. PC0TQ4BT-25). The study of dust composition in Moscow and Tiksi was supported by the Russian Science Foundation (grant no. 19-77-30004). Firn core collection on southern Spitsbergen, Svalbard, was co-funded by the Research Council of Norway, Arctic Field Grant 2018 (grant no. 282538), funds of the Leading National Research Centre (KNOW) received by the Centre for Polar Studies of the University of Silesia, and statutory activities 3841/E–41/S/2018 of the Ministry of Science and Higher Education of Poland. Czech Science Foundation projects 20-06168Y and GA20-20240S and Ministry of Education, Youth and Sports of the Czech Republic projects (nos. LM2015078 and CZ.02.1.01/0.0/0.0/16_013/0001708) were funders. The support of the EPOS-PL project (no. POIR.04.02.00-14-A003/16), co-financed by the European Union from the funds of the European Regional Development Fund (ERDF) to the laboratory facilities at IG PAS used in the study, is also appreciated. European Union COST Action InDust was also involved in funding. The preparation of this paper was partially funded by Icelandic Research Fund (Rannis) grant no. 207057-051. Outi Meinander wwas funded by the Academy of Finland (ACCC Flagship grant no. 337552 and BBrCAC no. 341271), H2020 EU-Interact (no. 730938), the International Arctic Science Committee (IASC Cross-Cutting grant), and the Ministry for Foreign Affairs of Finland (IBA project no. PC0TQ4BT-20). Denis Frolov was funded by the Lomonosov Moscow State University (state topic “Danger and risk of natural processes and phenomena” no. 121051300175-4 and “Evolution of the cryosphere under climate change and anthropogenic impact” no. 121051100164-0). Konrad Kandler was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation; grant nos. 264912134, 416816480, and 417012665). Nikolay Kasimov and Elena Aseyeva were funded by the Russian Science Foundation (No. 19-77-30004). Jame King was supported by NSERC Discovery 2016-05417, CFI 36564, and CMN RES00044975. Benjamin Murray, Alberto Sanchez-Marroquin, and Sarah Barr were supported by the European Research Council (648661 MarineIce) and the Natural Environment Research Council (NE/T00648X/1; NE/R006687/1). Ottmar Möhler and Nsikanabasi Silas Umo were funded by the Helmholtz Association of German Research Centres through its “Changing Earth – Sustaining our Future” program. Markku Kulmala, Nikolay Kasimov, and Olga Popovicheva were funded by the Russian Ministry of Education and Science (grant no. 075-15-2021-574). Keyvan Ranjbar and Norman T. O'Neill were funded by the PAHA project (NSERC-CCAR program; RGPCC-433842-2012), the SACIA project (CSA-ESSDA program; 16UASACIA), and the NSERC DG grant of O'Neill (grant no. RGPIN-05002-2014). Ivan Semenkov, Olga Popovicheva, and Nikolay Kasimov were funded by Lomonosov Moscow State University (Interdisciplinary Scientific and Educational School “Future Planet and Global Environmental Change” and project no. 121051400083-1). Zongbo Shi and Clarissa Baldo were funded by the UK Natural Environment Research Council (grant nos. NE/L002493/1 and NE/S00579X).

Publisher Copyright:
© 2022 Outi Meinander et al.

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MeinanderO2022NewlyFinal published version, 11.7 MBLicence: Creative Commons: Attribution (CC BY)

Cite this

Meinander, O., Dagsson-Waldhauserova, P., Amosov, P., Aseyeva, E., Atkins, C., Baklanov, A., Baldo, C., Barr, S. L., Barzycka, B., Benning, L. G., Cvetkovic, B., Enchilik, P., Frolov, D., Gassó, S., Kandler, K., Kasimov, N., Kavan, J., King, J., Koroleva, T., ... Vukovic Vimic, A. (2022). Newly identified climatically and environmentally significant high-latitude dust sources. Atmospheric Chemistry and Physics, 22(17), 11889-11930. https://doi.org/10.5194/acp-22-11889-2022

@article{a5b7e44b6d68498f81e6f302b6244db8,

title = "Newly identified climatically and environmentally significant high-latitude dust sources",

abstract = "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 >1670000 km2, >560000 km2, and >240000 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.",

author = "Outi Meinander and Pavla Dagsson-Waldhauserova and Pavel Amosov and Elena Aseyeva and Cliff Atkins and Alexander Baklanov and Clarissa Baldo and Barr, {Sarah L.} and Barbara Barzycka and Benning, {Liane G.} and Bojan Cvetkovic and Polina Enchilik and Denis Frolov and Santiago Gass{\'o} and Konrad Kandler and Nikolay Kasimov and Jan Kavan and James King and Tatyana Koroleva and Viktoria Krupskaya and Markku Kulmala and Monika Kusiak and Lappalainen, {Hanna K.} and Micha{\l} Laska and Jerome Lasne and Marek Lewandowski and Bart{\l}omiej Luks and Mcquaid, {James B.} and Beatrice Moroni and Benjamin Murray and Ottmar M{\"o}hler and Adam Nawrot and Slobodan Nickovic and O'neill, {Norman T.} and Goran Pejanovic and Olga Popovicheva and Keyvan Ranjbar and Manolis Romanias and Olga Samonova and Alberto Sanchez-Marroquin and Kerstin Schepanski and Ivan Semenkov and Anna Sharapova and Elena Shevnina and Zongbo Shi and Mikhail Sofiev and Fr{\'e}d{\'e}ric Thevenet and Throstur Thorsteinsson and Mikhail Timofeev and Umo, {Nsikanabasi Silas} and Andreas Uppstu and Darya Urupina and Gy{\"o}rgy Varga and Tomasz Werner and Olafur Arnalds and {Vukovic Vimic}, Ana",

note = "Funding Information: This research was supported by the Ministry for Foreign Affairs of Finland (IBA project no. PC0TQ4BT-25). The study of dust composition in Moscow and Tiksi was supported by the Russian Science Foundation (grant no. 19-77-30004). Firn core collection on southern Spitsbergen, Svalbard, was co-funded by the Research Council of Norway, Arctic Field Grant 2018 (grant no. 282538), funds of the Leading National Research Centre (KNOW) received by the Centre for Polar Studies of the University of Silesia, and statutory activities 3841/E–41/S/2018 of the Ministry of Science and Higher Education of Poland. Czech Science Foundation projects 20-06168Y and GA20-20240S and Ministry of Education, Youth and Sports of the Czech Republic projects (nos. LM2015078 and CZ.02.1.01/0.0/0.0/16_013/0001708) were funders. The support of the EPOS-PL project (no. POIR.04.02.00-14-A003/16), co-financed by the European Union from the funds of the European Regional Development Fund (ERDF) to the laboratory facilities at IG PAS used in the study, is also appreciated. European Union COST Action InDust was also involved in funding. The preparation of this paper was partially funded by Icelandic Research Fund (Rannis) grant no. 207057-051. Outi Meinander wwas funded by the Academy of Finland (ACCC Flagship grant no. 337552 and BBrCAC no. 341271), H2020 EU-Interact (no. 730938), the International Arctic Science Committee (IASC Cross-Cutting grant), and the Ministry for Foreign Affairs of Finland (IBA project no. PC0TQ4BT-20). Denis Frolov was funded by the Lomonosov Moscow State University (state topic “Danger and risk of natural processes and phenomena” no. 121051300175-4 and “Evolution of the cryosphere under climate change and anthropogenic impact” no. 121051100164-0). Konrad Kandler was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation; grant nos. 264912134, 416816480, and 417012665). Nikolay Kasimov and Elena Aseyeva were funded by the Russian Science Foundation (No. 19-77-30004). Jame King was supported by NSERC Discovery 2016-05417, CFI 36564, and CMN RES00044975. Benjamin Murray, Alberto Sanchez-Marroquin, and Sarah Barr were supported by the European Research Council (648661 MarineIce) and the Natural Environment Research Council (NE/T00648X/1; NE/R006687/1). Ottmar M{\"o}hler and Nsikanabasi Silas Umo were funded by the Helmholtz Association of German Research Centres through its “Changing Earth – Sustaining our Future” program. Markku Kulmala, Nikolay Kasimov, and Olga Popovicheva were funded by the Russian Ministry of Education and Science (grant no. 075-15-2021-574). Keyvan Ranjbar and Norman T. O'Neill were funded by the PAHA project (NSERC-CCAR program; RGPCC-433842-2012), the SACIA project (CSA-ESSDA program; 16UASACIA), and the NSERC DG grant of O'Neill (grant no. RGPIN-05002-2014). Ivan Semenkov, Olga Popovicheva, and Nikolay Kasimov were funded by Lomonosov Moscow State University (Interdisciplinary Scientific and Educational School “Future Planet and Global Environmental Change” and project no. 121051400083-1). Zongbo Shi and Clarissa Baldo were funded by the UK Natural Environment Research Council (grant nos. NE/L002493/1 and NE/S00579X). Publisher Copyright: {\textcopyright} 2022 Outi Meinander et al.",

year = "2022",

month = sep,

day = "14",

doi = "10.5194/acp-22-11889-2022",

language = "English",

volume = "22",

pages = "11889--11930",

journal = "Atmospheric Chemistry and Physics",

issn = "1680-7316",

publisher = "Copernicus Publications",

number = "17",

}

Meinander, O, Dagsson-Waldhauserova, P, Amosov, P, Aseyeva, E, Atkins, C, Baklanov, A, Baldo, C, Barr, SL, Barzycka, B, Benning, LG, Cvetkovic, B, Enchilik, P, Frolov, D, Gassó, S, Kandler, K, Kasimov, N, Kavan, J, King, J, Koroleva, T, Krupskaya, V, Kulmala, M, Kusiak, M, Lappalainen, HK, Laska, M, Lasne, J, Lewandowski, M, Luks, B, Mcquaid, JB, Moroni, B, Murray, B, Möhler, O, Nawrot, A, Nickovic, S, O'neill, NT, Pejanovic, G, Popovicheva, O, Ranjbar, K, Romanias, M, Samonova, O, Sanchez-Marroquin, A, Schepanski, K, Semenkov, I, Sharapova, A, Shevnina, E, Shi, Z, Sofiev, M, Thevenet, F, Thorsteinsson, T, Timofeev, M, Umo, NS, Uppstu, A, Urupina, D, Varga, G, Werner, T, Arnalds, O & Vukovic Vimic, A 2022, 'Newly identified climatically and environmentally significant high-latitude dust sources', Atmospheric Chemistry and Physics, vol. 22, no. 17, pp. 11889-11930. https://doi.org/10.5194/acp-22-11889-2022

TY - JOUR

T1 - Newly identified climatically and environmentally significant high-latitude dust sources

AU - Meinander, Outi

AU - Dagsson-Waldhauserova, Pavla

AU - Amosov, Pavel

AU - Aseyeva, Elena

AU - Atkins, Cliff

AU - Baklanov, Alexander

AU - Baldo, Clarissa

AU - Barr, Sarah L.

AU - Barzycka, Barbara

AU - Benning, Liane G.

AU - Cvetkovic, Bojan

AU - Enchilik, Polina

AU - Frolov, Denis

AU - Gassó, Santiago

AU - Kandler, Konrad

AU - Kasimov, Nikolay

AU - Kavan, Jan

AU - King, James

AU - Koroleva, Tatyana

AU - Krupskaya, Viktoria

AU - Kulmala, Markku

AU - Kusiak, Monika

AU - Lappalainen, Hanna K.

AU - Laska, Michał

AU - Lasne, Jerome

AU - Lewandowski, Marek

AU - Luks, Bartłomiej

AU - Mcquaid, James B.

AU - Moroni, Beatrice

AU - Murray, Benjamin

AU - Möhler, Ottmar

AU - Nawrot, Adam

AU - Nickovic, Slobodan

AU - O'neill, Norman T.

AU - Pejanovic, Goran

AU - Popovicheva, Olga

AU - Ranjbar, Keyvan

AU - Romanias, Manolis

AU - Samonova, Olga

AU - Sanchez-Marroquin, Alberto

AU - Schepanski, Kerstin

AU - Semenkov, Ivan

AU - Sharapova, Anna

AU - Shevnina, Elena

AU - Shi, Zongbo

AU - Sofiev, Mikhail

AU - Thevenet, Frédéric

AU - Thorsteinsson, Throstur

AU - Timofeev, Mikhail

AU - Umo, Nsikanabasi Silas

AU - Uppstu, Andreas

AU - Urupina, Darya

AU - Varga, György

AU - Werner, Tomasz

AU - Arnalds, Olafur

AU - Vukovic Vimic, Ana

N1 - Funding Information: This research was supported by the Ministry for Foreign Affairs of Finland (IBA project no. PC0TQ4BT-25). The study of dust composition in Moscow and Tiksi was supported by the Russian Science Foundation (grant no. 19-77-30004). Firn core collection on southern Spitsbergen, Svalbard, was co-funded by the Research Council of Norway, Arctic Field Grant 2018 (grant no. 282538), funds of the Leading National Research Centre (KNOW) received by the Centre for Polar Studies of the University of Silesia, and statutory activities 3841/E–41/S/2018 of the Ministry of Science and Higher Education of Poland. Czech Science Foundation projects 20-06168Y and GA20-20240S and Ministry of Education, Youth and Sports of the Czech Republic projects (nos. LM2015078 and CZ.02.1.01/0.0/0.0/16_013/0001708) were funders. The support of the EPOS-PL project (no. POIR.04.02.00-14-A003/16), co-financed by the European Union from the funds of the European Regional Development Fund (ERDF) to the laboratory facilities at IG PAS used in the study, is also appreciated. European Union COST Action InDust was also involved in funding. The preparation of this paper was partially funded by Icelandic Research Fund (Rannis) grant no. 207057-051. Outi Meinander wwas funded by the Academy of Finland (ACCC Flagship grant no. 337552 and BBrCAC no. 341271), H2020 EU-Interact (no. 730938), the International Arctic Science Committee (IASC Cross-Cutting grant), and the Ministry for Foreign Affairs of Finland (IBA project no. PC0TQ4BT-20). Denis Frolov was funded by the Lomonosov Moscow State University (state topic “Danger and risk of natural processes and phenomena” no. 121051300175-4 and “Evolution of the cryosphere under climate change and anthropogenic impact” no. 121051100164-0). Konrad Kandler was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation; grant nos. 264912134, 416816480, and 417012665). Nikolay Kasimov and Elena Aseyeva were funded by the Russian Science Foundation (No. 19-77-30004). Jame King was supported by NSERC Discovery 2016-05417, CFI 36564, and CMN RES00044975. Benjamin Murray, Alberto Sanchez-Marroquin, and Sarah Barr were supported by the European Research Council (648661 MarineIce) and the Natural Environment Research Council (NE/T00648X/1; NE/R006687/1). Ottmar Möhler and Nsikanabasi Silas Umo were funded by the Helmholtz Association of German Research Centres through its “Changing Earth – Sustaining our Future” program. Markku Kulmala, Nikolay Kasimov, and Olga Popovicheva were funded by the Russian Ministry of Education and Science (grant no. 075-15-2021-574). Keyvan Ranjbar and Norman T. O'Neill were funded by the PAHA project (NSERC-CCAR program; RGPCC-433842-2012), the SACIA project (CSA-ESSDA program; 16UASACIA), and the NSERC DG grant of O'Neill (grant no. RGPIN-05002-2014). Ivan Semenkov, Olga Popovicheva, and Nikolay Kasimov were funded by Lomonosov Moscow State University (Interdisciplinary Scientific and Educational School “Future Planet and Global Environmental Change” and project no. 121051400083-1). Zongbo Shi and Clarissa Baldo were funded by the UK Natural Environment Research Council (grant nos. NE/L002493/1 and NE/S00579X). Publisher Copyright: © 2022 Outi Meinander et al.

PY - 2022/9/14

Y1 - 2022/9/14

N2 - 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 >1670000 km2, >560000 km2, and >240000 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.

AB - 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 >1670000 km2, >560000 km2, and >240000 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.

UR - http://www.scopus.com/inward/record.url?scp=85139596246&partnerID=8YFLogxK

U2 - 10.5194/acp-22-11889-2022

DO - 10.5194/acp-22-11889-2022

M3 - Article

AN - SCOPUS:85139596246

SN - 1680-7316

VL - 22

SP - 11889

EP - 11930

JO - Atmospheric Chemistry and Physics

JF - Atmospheric Chemistry and Physics

IS - 17

ER -

Newly identified climatically and environmentally significant high-latitude dust sources

Abstract

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