Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas

Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas

<p>Anthropogenic activities on the Indo-Gangetic Plain emit vast amounts of light-absorbing particles (LAPs) into the atmosphere, modifying the atmospheric radiation state. With transport to the nearby Himalayas and deposition to its surfaces the particles contribute to glacier melt and snowme...

Full description

Bibliographic Details
Main Authors: J. Svensson, J. Ström, H. Honkanen, E. Asmi, N. B. Dkhar, S. Tayal, V. P. Sharma, R. Hooda, M. Leppäranta, H.-W. Jacobi, H. Lihavainen, A. Hyvärinen
Format: Article
Language:English
Published: Copernicus Publications 2021-02-01
Series:Atmospheric Chemistry and Physics
Online Access:https://acp.copernicus.org/articles/21/2931/2021/acp-21-2931-2021.pdf
id doaj-3db6bef43d4644cf81318b3f9a2c2eb0
record_format Article
collection DOAJ
language English
format Article
sources DOAJ
author J. Svensson
J. Svensson
J. Ström
H. Honkanen
E. Asmi
N. B. Dkhar
S. Tayal
S. Tayal
V. P. Sharma
V. P. Sharma
R. Hooda
M. Leppäranta
H.-W. Jacobi
H. Lihavainen
H. Lihavainen
A. Hyvärinen
spellingShingle J. Svensson
J. Svensson
J. Ström
H. Honkanen
E. Asmi
N. B. Dkhar
S. Tayal
S. Tayal
V. P. Sharma
V. P. Sharma
R. Hooda
M. Leppäranta
H.-W. Jacobi
H. Lihavainen
H. Lihavainen
A. Hyvärinen
Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas
Atmospheric Chemistry and Physics
author_facet J. Svensson
J. Svensson
J. Ström
H. Honkanen
E. Asmi
N. B. Dkhar
S. Tayal
S. Tayal
V. P. Sharma
V. P. Sharma
R. Hooda
M. Leppäranta
H.-W. Jacobi
H. Lihavainen
H. Lihavainen
A. Hyvärinen
author_sort J. Svensson
title Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas
title_short Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas
title_full Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas
title_fullStr Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas
title_full_unstemmed Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central Himalayas
title_sort deposition of light-absorbing particles in glacier snow of the sunderdhunga valley, the southern forefront of the central himalayas
publisher Copernicus Publications
series Atmospheric Chemistry and Physics
issn 1680-7316
1680-7324
publishDate 2021-02-01
description <p>Anthropogenic activities on the Indo-Gangetic Plain emit vast amounts of light-absorbing particles (LAPs) into the atmosphere, modifying the atmospheric radiation state. With transport to the nearby Himalayas and deposition to its surfaces the particles contribute to glacier melt and snowmelt via darkening of the highly reflective snow. The central Himalayas have been identified as a region where LAPs are especially pronounced in glacier snow but still remain a region where measurements of LAPs in the snow are scarce. Here we study the deposition of LAPs in five snow pits sampled in 2016 (and one from 2015) within 1 km from each other from two glaciers in the Sunderdhunga Valley, in the state of Uttarakhand, India, in the central Himalayas. The snow pits display a distinct enriched LAP layer interleaved by younger snow above and older snow below. The LAPs exhibit a distinct vertical distribution in these different snow layers. For the analyzed elemental carbon (EC), the younger snow layers in the different pits show similarities, which can be characterized by a deposition constant of about 50 <span class="inline-formula">µ</span>g m<span class="inline-formula"><sup>−2</sup></span> mm<span class="inline-formula"><sup>−1</sup></span> snow water equivalent (SWE), while the old-snow layers also indicate similar values, described by a deposition constant of roughly 150 <span class="inline-formula">µ</span>g m<span class="inline-formula"><sup>−2</sup></span> mm<span class="inline-formula"><sup>−1</sup></span> SWE. The enriched LAP layer, contrarily, displays no similar trends between the pits. Instead, it is characterized by very high amounts of LAPs and differ in orders of magnitude for concentration between the pits. The enriched LAP layer is likely a result of strong melting that took place during the summers of 2015 and 2016, as well as possible lateral transport of LAPs. The mineral dust fractional absorption is slightly below 50 % for the young- and old-snow layers, whereas it is the dominating light-absorbing constituent in the enriched LAP layer, thus, highlighting the importance of dust in the region. Our results indicate the problems with complex topography in the Himalayas but, nonetheless, can be useful in large-scale assessments of LAPs in Himalayan snow.</p>
url https://acp.copernicus.org/articles/21/2931/2021/acp-21-2931-2021.pdf
work_keys_str_mv AT jsvensson depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT jsvensson depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT jstrom depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT hhonkanen depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT easmi depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT nbdkhar depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT stayal depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT stayal depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT vpsharma depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT vpsharma depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT rhooda depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT mlepparanta depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT hwjacobi depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT hlihavainen depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT hlihavainen depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
AT ahyvarinen depositionoflightabsorbingparticlesinglaciersnowofthesunderdhungavalleythesouthernforefrontofthecentralhimalayas
_version_ 1724249657359466496
spelling doaj-3db6bef43d4644cf81318b3f9a2c2eb02021-02-26T11:07:10ZengCopernicus PublicationsAtmospheric Chemistry and Physics1680-73161680-73242021-02-01212931294310.5194/acp-21-2931-2021Deposition of light-absorbing particles in glacier snow of the Sunderdhunga Valley, the southern forefront of the central HimalayasJ. Svensson0J. Svensson1J. Ström2H. Honkanen3E. Asmi4N. B. Dkhar5S. Tayal6S. Tayal7V. P. Sharma8V. P. Sharma9R. Hooda10M. Leppäranta11H.-W. Jacobi12H. Lihavainen13H. Lihavainen14A. Hyvärinen15Atmospheric Composition Research, Finnish Meteorological Institute, Helsinki, FinlandUniversité Grenoble Alpes, CNRS, IRD, INP-G, IGE, Grenoble, FranceDepartment of Environmental Science, Stockholm University, Stockholm, SwedenInstitute for Atmospheric and Earth System Research, Faculty of Science, University of Helsinki, Helsinki, FinlandAtmospheric Composition Research, Finnish Meteorological Institute, Helsinki, FinlandThe Energy and Resource Institute (TERI), New Delhi, IndiaThe Energy and Resource Institute (TERI), New Delhi, IndiaTERI School of Advanced Studies (TERI SAS), New Delhi, IndiaThe Energy and Resource Institute (TERI), New Delhi, IndiaTERI School of Advanced Studies (TERI SAS), New Delhi, IndiaAtmospheric Composition Research, Finnish Meteorological Institute, Helsinki, FinlandInstitute for Atmospheric and Earth System Research, Faculty of Science, University of Helsinki, Helsinki, FinlandUniversité Grenoble Alpes, CNRS, IRD, INP-G, IGE, Grenoble, FranceAtmospheric Composition Research, Finnish Meteorological Institute, Helsinki, FinlandSvalbard Integrated Arctic Earth Observing System, Longyearbyen, NorwayAtmospheric Composition Research, Finnish Meteorological Institute, Helsinki, Finland<p>Anthropogenic activities on the Indo-Gangetic Plain emit vast amounts of light-absorbing particles (LAPs) into the atmosphere, modifying the atmospheric radiation state. With transport to the nearby Himalayas and deposition to its surfaces the particles contribute to glacier melt and snowmelt via darkening of the highly reflective snow. The central Himalayas have been identified as a region where LAPs are especially pronounced in glacier snow but still remain a region where measurements of LAPs in the snow are scarce. Here we study the deposition of LAPs in five snow pits sampled in 2016 (and one from 2015) within 1 km from each other from two glaciers in the Sunderdhunga Valley, in the state of Uttarakhand, India, in the central Himalayas. The snow pits display a distinct enriched LAP layer interleaved by younger snow above and older snow below. The LAPs exhibit a distinct vertical distribution in these different snow layers. For the analyzed elemental carbon (EC), the younger snow layers in the different pits show similarities, which can be characterized by a deposition constant of about 50 <span class="inline-formula">µ</span>g m<span class="inline-formula"><sup>−2</sup></span> mm<span class="inline-formula"><sup>−1</sup></span> snow water equivalent (SWE), while the old-snow layers also indicate similar values, described by a deposition constant of roughly 150 <span class="inline-formula">µ</span>g m<span class="inline-formula"><sup>−2</sup></span> mm<span class="inline-formula"><sup>−1</sup></span> SWE. The enriched LAP layer, contrarily, displays no similar trends between the pits. Instead, it is characterized by very high amounts of LAPs and differ in orders of magnitude for concentration between the pits. The enriched LAP layer is likely a result of strong melting that took place during the summers of 2015 and 2016, as well as possible lateral transport of LAPs. The mineral dust fractional absorption is slightly below 50 % for the young- and old-snow layers, whereas it is the dominating light-absorbing constituent in the enriched LAP layer, thus, highlighting the importance of dust in the region. Our results indicate the problems with complex topography in the Himalayas but, nonetheless, can be useful in large-scale assessments of LAPs in Himalayan snow.</p>https://acp.copernicus.org/articles/21/2931/2021/acp-21-2931-2021.pdf

Similar Items