The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures

In recent years, sea spray as well as the biological material it contains has received increased attention as a source of ice-nucleating particles (INPs). Such INPs may play a role in remote marine regions, where other sources of INPs are scarce or absent. In the Arctic, these INPs can influence wat...

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Published in:Atmospheric Chemistry and Physics
Main Authors: Ickes, Luisa, Porter, Grace C. E., Wagner, Robert, Adams, Michael P., Bierbauer, Sascha, Bertram, Allan K., Bilde, Merete, Christiansen, Sigurd, Ekman, Annica M. L., Gorokhova, Elena, Höhler, Kristina, Kiselev, Alexei A., Leck, Caroline, Möhler, Ottmar, Murray, Benjamin J., Schiebel, Thea, Ullrich, Romy, Salter, Matthew E.
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2020
Subjects:
article
Verlagsveröffentlichung
Arctic
Phytoplankton
Sea ice
Online Access:https://doi.org/10.5194/acp-20-11089-2020
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language English
topic article
Verlagsveröffentlichung
spellingShingle article
Verlagsveröffentlichung
Ickes, Luisa
Porter, Grace C. E.
Wagner, Robert
Adams, Michael P.
Bierbauer, Sascha
Bertram, Allan K.
Bilde, Merete
Christiansen, Sigurd
Ekman, Annica M. L.
Gorokhova, Elena
Höhler, Kristina
Kiselev, Alexei A.
Leck, Caroline
Möhler, Ottmar
Murray, Benjamin J.
Schiebel, Thea
Ullrich, Romy
Salter, Matthew E.
The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures
topic_facet article
Verlagsveröffentlichung
description In recent years, sea spray as well as the biological material it contains has received increased attention as a source of ice-nucleating particles (INPs). Such INPs may play a role in remote marine regions, where other sources of INPs are scarce or absent. In the Arctic, these INPs can influence water–ice partitioning in low-level clouds and thereby the cloud lifetime, with consequences for the surface energy budget, sea ice formation and melt, and climate. Marine aerosol is of a diverse nature, so identifying sources of INPs is challenging. One fraction of marine bioaerosol (phytoplankton and their exudates) has been a particular focus of marine INP research. In our study we attempt to address three main questions. Firstly, we compare the ice-nucleating ability of two common phytoplankton species with Arctic seawater microlayer samples using the same instrumentation to see if these phytoplankton species produce ice-nucleating material with sufficient activity to account for the ice nucleation observed in Arctic microlayer samples. We present the first measurements of the ice-nucleating ability of two predominant phytoplankton species: Melosira arctica, a common Arctic diatom species, and Skeletonema marinoi, a ubiquitous diatom species across oceans worldwide. To determine the potential effect of nutrient conditions and characteristics of the algal culture, such as the amount of organic carbon associated with algal cells, on the ice nucleation activity, Skeletonema marinoi was grown under different nutrient regimes. From comparison of the ice nucleation data of the algal cultures to those obtained from a range of sea surface microlayer (SML) samples obtained during three different field expeditions to the Arctic (ACCACIA, NETCARE, and ASCOS), we found that they were not as ice active as the investigated microlayer samples, although these diatoms do produce ice-nucleating material. Secondly, to improve our understanding of local Arctic marine sources as atmospheric INPs we applied two aerosolization techniques to analyse the ice-nucleating ability of aerosolized microlayer and algal samples. The aerosols were generated either by direct nebulization of the undiluted bulk solutions or by the addition of the samples to a sea spray simulation chamber filled with artificial seawater. The latter method generates aerosol particles using a plunging jet to mimic the process of oceanic wave breaking. We observed that the aerosols produced using this approach can be ice active, indicating that the ice-nucleating material in seawater can indeed transfer to the aerosol phase. Thirdly, we attempted to measure ice nucleation activity across the entire temperature range relevant for mixed-phase clouds using a suite of ice nucleation measurement techniques – an expansion cloud chamber, a continuous-flow diffusion chamber, and a cold stage. In order to compare the measurements made using the different instruments, we have normalized the data in relation to the mass of salt present in the nascent sea spray aerosol. At temperatures above 248 K some of the SML samples were very effective at nucleating ice, but there was substantial variability between the different samples. In contrast, there was much less variability between samples below 248 K. We discuss our results in the context of aerosol–cloud interactions in the Arctic with a focus on furthering our understanding of which INP types may be important in the Arctic atmosphere.
format Article in Journal/Newspaper
author Ickes, Luisa
Porter, Grace C. E.
Wagner, Robert
Adams, Michael P.
Bierbauer, Sascha
Bertram, Allan K.
Bilde, Merete
Christiansen, Sigurd
Ekman, Annica M. L.
Gorokhova, Elena
Höhler, Kristina
Kiselev, Alexei A.
Leck, Caroline
Möhler, Ottmar
Murray, Benjamin J.
Schiebel, Thea
Ullrich, Romy
Salter, Matthew E.
author_facet Ickes, Luisa
Porter, Grace C. E.
Wagner, Robert
Adams, Michael P.
Bierbauer, Sascha
Bertram, Allan K.
Bilde, Merete
Christiansen, Sigurd
Ekman, Annica M. L.
Gorokhova, Elena
Höhler, Kristina
Kiselev, Alexei A.
Leck, Caroline
Möhler, Ottmar
Murray, Benjamin J.
Schiebel, Thea
Ullrich, Romy
Salter, Matthew E.
author_sort Ickes, Luisa
title The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures
title_short The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures
title_full The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures
title_fullStr The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures
title_full_unstemmed The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures
title_sort ice-nucleating activity of arctic sea surface microlayer samples and marine algal cultures
publisher Copernicus Publications
publishDate 2020
url https://doi.org/10.5194/acp-20-11089-2020
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https://acp.copernicus.org/articles/20/11089/2020/acp-20-11089-2020.pdf
geographic Arctic
geographic_facet Arctic
genre Arctic
Phytoplankton
Sea ice
genre_facet Arctic
Phytoplankton
Sea ice
op_relation Atmospheric Chemistry and Physics -- http://www.atmos-chem-phys.net/volumes_and_issues.html -- http://www.bibliothek.uni-regensburg.de/ezeit/?2069847 -- 1680-7324
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op_doi https://doi.org/10.5194/acp-20-11089-2020
container_title Atmospheric Chemistry and Physics
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spelling ftnonlinearchiv:oai:noa.gwlb.de:cop_mods_00054153 2023-05-15T14:48:46+02:00 The ice-nucleating activity of Arctic sea surface microlayer samples and marine algal cultures Ickes, Luisa Porter, Grace C. E. Wagner, Robert Adams, Michael P. Bierbauer, Sascha Bertram, Allan K. Bilde, Merete Christiansen, Sigurd Ekman, Annica M. L. Gorokhova, Elena Höhler, Kristina Kiselev, Alexei A. Leck, Caroline Möhler, Ottmar Murray, Benjamin J. Schiebel, Thea Ullrich, Romy Salter, Matthew E. 2020-09 electronic https://doi.org/10.5194/acp-20-11089-2020 https://noa.gwlb.de/receive/cop_mods_00054153 https://noa.gwlb.de/servlets/MCRFileNodeServlet/cop_derivate_00053804/acp-20-11089-2020.pdf https://acp.copernicus.org/articles/20/11089/2020/acp-20-11089-2020.pdf eng eng Copernicus Publications Atmospheric Chemistry and Physics -- http://www.atmos-chem-phys.net/volumes_and_issues.html -- http://www.bibliothek.uni-regensburg.de/ezeit/?2069847 -- 1680-7324 https://doi.org/10.5194/acp-20-11089-2020 https://noa.gwlb.de/receive/cop_mods_00054153 https://noa.gwlb.de/servlets/MCRFileNodeServlet/cop_derivate_00053804/acp-20-11089-2020.pdf https://acp.copernicus.org/articles/20/11089/2020/acp-20-11089-2020.pdf https://creativecommons.org/licenses/by/4.0/ uneingeschränkt info:eu-repo/semantics/openAccess CC-BY article Verlagsveröffentlichung article Text doc-type:article 2020 ftnonlinearchiv https://doi.org/10.5194/acp-20-11089-2020 2022-02-08T22:35:08Z In recent years, sea spray as well as the biological material it contains has received increased attention as a source of ice-nucleating particles (INPs). Such INPs may play a role in remote marine regions, where other sources of INPs are scarce or absent. In the Arctic, these INPs can influence water–ice partitioning in low-level clouds and thereby the cloud lifetime, with consequences for the surface energy budget, sea ice formation and melt, and climate. Marine aerosol is of a diverse nature, so identifying sources of INPs is challenging. One fraction of marine bioaerosol (phytoplankton and their exudates) has been a particular focus of marine INP research. In our study we attempt to address three main questions. Firstly, we compare the ice-nucleating ability of two common phytoplankton species with Arctic seawater microlayer samples using the same instrumentation to see if these phytoplankton species produce ice-nucleating material with sufficient activity to account for the ice nucleation observed in Arctic microlayer samples. We present the first measurements of the ice-nucleating ability of two predominant phytoplankton species: Melosira arctica, a common Arctic diatom species, and Skeletonema marinoi, a ubiquitous diatom species across oceans worldwide. To determine the potential effect of nutrient conditions and characteristics of the algal culture, such as the amount of organic carbon associated with algal cells, on the ice nucleation activity, Skeletonema marinoi was grown under different nutrient regimes. From comparison of the ice nucleation data of the algal cultures to those obtained from a range of sea surface microlayer (SML) samples obtained during three different field expeditions to the Arctic (ACCACIA, NETCARE, and ASCOS), we found that they were not as ice active as the investigated microlayer samples, although these diatoms do produce ice-nucleating material. Secondly, to improve our understanding of local Arctic marine sources as atmospheric INPs we applied two aerosolization techniques to analyse the ice-nucleating ability of aerosolized microlayer and algal samples. The aerosols were generated either by direct nebulization of the undiluted bulk solutions or by the addition of the samples to a sea spray simulation chamber filled with artificial seawater. The latter method generates aerosol particles using a plunging jet to mimic the process of oceanic wave breaking. We observed that the aerosols produced using this approach can be ice active, indicating that the ice-nucleating material in seawater can indeed transfer to the aerosol phase. Thirdly, we attempted to measure ice nucleation activity across the entire temperature range relevant for mixed-phase clouds using a suite of ice nucleation measurement techniques – an expansion cloud chamber, a continuous-flow diffusion chamber, and a cold stage. In order to compare the measurements made using the different instruments, we have normalized the data in relation to the mass of salt present in the nascent sea spray aerosol. At temperatures above 248 K some of the SML samples were very effective at nucleating ice, but there was substantial variability between the different samples. In contrast, there was much less variability between samples below 248 K. We discuss our results in the context of aerosol–cloud interactions in the Arctic with a focus on furthering our understanding of which INP types may be important in the Arctic atmosphere. Article in Journal/Newspaper Arctic Phytoplankton Sea ice Niedersächsisches Online-Archiv NOA Arctic Atmospheric Chemistry and Physics 20 18 11089 11117

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