Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago

Summertime Arctic aerosol size distributions are strongly controlled by natural regional emissions. Within this context, we use a chemical transport model with size-resolved aerosol microphysics (GEOS-Chem-TOMAS) to interpret measurements of aerosol size distributions from the Canadian Arctic Archip...

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Published in:Atmospheric Chemistry and Physics
Main Authors: Croft, Betty, Martin, Randall V., Leaitch, W. Richard, Burkart, Julia, Chang, Rachel Y.-W., Collins, Douglas B., Hayes, Patrick L., Hodshire, Anna L., Huang, Lin, Kodros, John K., Moravek, Alexander, Mungall, Emma L., Murphy, Jennifer G., Sharma, Sangeeta, Tremblay, Samantha, Wentworth, Gregory R., Willis, Megan D., Abbatt, Jonathan P. D., Pierce, Jeffrey R.
Format: Text
Language:English
Published: 2019
Subjects:
Arctic
Canadian Arctic Archipelago
Eureka
albedo
Arctic Archipelago
Online Access:https://doi.org/10.5194/acp-19-2787-2019
https://www.atmos-chem-phys.net/19/2787/2019/
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collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description Summertime Arctic aerosol size distributions are strongly controlled by natural regional emissions. Within this context, we use a chemical transport model with size-resolved aerosol microphysics (GEOS-Chem-TOMAS) to interpret measurements of aerosol size distributions from the Canadian Arctic Archipelago during the summer of 2016, as part of the “NETwork on Climate and Aerosols: Addressing key uncertainties in Remote Canadian Environments” (NETCARE) project. Our simulations suggest that condensation of secondary organic aerosol (SOA) from precursor vapors emitted in the Arctic and near Arctic marine (ice-free seawater) regions plays a key role in particle growth events that shape the aerosol size distributions observed at Alert (82.5 ∘ N, 62.3 ∘ W), Eureka (80.1 ∘ N, 86.4 ∘ W), and along a NETCARE ship track within the Archipelago. We refer to this SOA as Arctic marine SOA (AMSOA) to reflect the Arctic marine-based and likely biogenic sources for the precursors of the condensing organic vapors. AMSOA from a simulated flux (500 <math xmlns="http://www.w3.org/1998/Math/MathML" id="M5" display="inline" overflow="scroll" dspmath="mathml"><mrow class="unit"><mi mathvariant="normal">µ</mi><mi mathvariant="normal">g</mi><mspace linebreak="nobreak" width="0.125em"/><msup><mi mathvariant="normal">m</mi><mrow><mo>-</mo><mn mathvariant="normal">2</mn></mrow></msup><mspace linebreak="nobreak" width="0.125em"/><msup><mi mathvariant="normal">day</mi><mrow><mo>-</mo><mn mathvariant="normal">1</mn></mrow></msup></mrow></math> <svg:svg xmlns:svg="http://www.w3.org/2000/svg" width="64pt" height="15pt" class="svg-formula" dspmath="mathimg" md5hash="8f93b7fde00f18c6b1eb9f6df658301c"><svg:image xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="acp-19-2787-2019-ie00001.svg" width="64pt" height="15pt" src="acp-19-2787-2019-ie00001.png"/></svg:svg> , north of 50 ∘ N) of precursor vapors (with an assumed yield of unity) reduces the summertime particle size distribution model–observation mean fractional error 2- to 4-fold, relative to a simulation without this AMSOA. Particle growth due to the condensable organic vapor flux contributes strongly (30 %–50 %) to the simulated summertime-mean number of particles with diameters larger than 20 nm in the study region. This growth couples with ternary particle nucleation (sulfuric acid, ammonia, and water vapor) and biogenic sulfate condensation to account for more than 90 % of this simulated particle number, which represents a strong biogenic influence. The simulated fit to summertime size-distribution observations is further improved at Eureka and for the ship track by scaling up the nucleation rate by a factor of 100 to account for other particle precursors such as gas-phase iodine and/or amines and/or fragmenting primary particles that could be missing from our simulations. Additionally, the fits to the observed size distributions and total aerosol number concentrations for particles larger than 4 nm improve with the assumption that the AMSOA contains semi-volatile species: the model–observation mean fractional error is reduced 2- to 3-fold for the Alert and ship track size distributions. AMSOA accounts for about half of the simulated particle surface area and volume distributions in the summertime Canadian Arctic Archipelago, with climate-relevant simulated summertime pan-Arctic-mean top-of-the-atmosphere aerosol direct ( −0.04 W m −2 ) and cloud-albedo indirect ( −0.4 W m −2 ) radiative effects, which due to uncertainties are viewed as an order of magnitude estimate. Future work should focus on further understanding summertime Arctic sources of AMSOA.
format Text
author Croft, Betty
Martin, Randall V.
Leaitch, W. Richard
Burkart, Julia
Chang, Rachel Y.-W.
Collins, Douglas B.
Hayes, Patrick L.
Hodshire, Anna L.
Huang, Lin
Kodros, John K.
Moravek, Alexander
Mungall, Emma L.
Murphy, Jennifer G.
Sharma, Sangeeta
Tremblay, Samantha
Wentworth, Gregory R.
Willis, Megan D.
Abbatt, Jonathan P. D.
Pierce, Jeffrey R.
spellingShingle Croft, Betty
Martin, Randall V.
Leaitch, W. Richard
Burkart, Julia
Chang, Rachel Y.-W.
Collins, Douglas B.
Hayes, Patrick L.
Hodshire, Anna L.
Huang, Lin
Kodros, John K.
Moravek, Alexander
Mungall, Emma L.
Murphy, Jennifer G.
Sharma, Sangeeta
Tremblay, Samantha
Wentworth, Gregory R.
Willis, Megan D.
Abbatt, Jonathan P. D.
Pierce, Jeffrey R.
Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago
author_facet Croft, Betty
Martin, Randall V.
Leaitch, W. Richard
Burkart, Julia
Chang, Rachel Y.-W.
Collins, Douglas B.
Hayes, Patrick L.
Hodshire, Anna L.
Huang, Lin
Kodros, John K.
Moravek, Alexander
Mungall, Emma L.
Murphy, Jennifer G.
Sharma, Sangeeta
Tremblay, Samantha
Wentworth, Gregory R.
Willis, Megan D.
Abbatt, Jonathan P. D.
Pierce, Jeffrey R.
author_sort Croft, Betty
title Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago
title_short Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago
title_full Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago
title_fullStr Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago
title_full_unstemmed Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago
title_sort arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the canadian arctic archipelago
publishDate 2019
url https://doi.org/10.5194/acp-19-2787-2019
https://www.atmos-chem-phys.net/19/2787/2019/
long_lat ENVELOPE(-85.940,-85.940,79.990,79.990)
geographic Arctic
Canadian Arctic Archipelago
Eureka
geographic_facet Arctic
Canadian Arctic Archipelago
Eureka
genre albedo
Arctic Archipelago
Arctic
Canadian Arctic Archipelago
genre_facet albedo
Arctic Archipelago
Arctic
Canadian Arctic Archipelago
op_source eISSN: 1680-7324
op_relation doi:10.5194/acp-19-2787-2019
https://www.atmos-chem-phys.net/19/2787/2019/
op_doi https://doi.org/10.5194/acp-19-2787-2019
container_title Atmospheric Chemistry and Physics
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spelling ftcopernicus:oai:publications.copernicus.org:acp71128 2023-05-15T13:11:30+02:00 Arctic marine secondary organic aerosol contributes significantly to summertime particle size distributions in the Canadian Arctic Archipelago Croft, Betty Martin, Randall V. Leaitch, W. Richard Burkart, Julia Chang, Rachel Y.-W. Collins, Douglas B. Hayes, Patrick L. Hodshire, Anna L. Huang, Lin Kodros, John K. Moravek, Alexander Mungall, Emma L. Murphy, Jennifer G. Sharma, Sangeeta Tremblay, Samantha Wentworth, Gregory R. Willis, Megan D. Abbatt, Jonathan P. D. Pierce, Jeffrey R. 2019-03-04 application/pdf https://doi.org/10.5194/acp-19-2787-2019 https://www.atmos-chem-phys.net/19/2787/2019/ eng eng doi:10.5194/acp-19-2787-2019 https://www.atmos-chem-phys.net/19/2787/2019/ eISSN: 1680-7324 Text 2019 ftcopernicus https://doi.org/10.5194/acp-19-2787-2019 2019-12-24T09:49:25Z Summertime Arctic aerosol size distributions are strongly controlled by natural regional emissions. Within this context, we use a chemical transport model with size-resolved aerosol microphysics (GEOS-Chem-TOMAS) to interpret measurements of aerosol size distributions from the Canadian Arctic Archipelago during the summer of 2016, as part of the “NETwork on Climate and Aerosols: Addressing key uncertainties in Remote Canadian Environments” (NETCARE) project. Our simulations suggest that condensation of secondary organic aerosol (SOA) from precursor vapors emitted in the Arctic and near Arctic marine (ice-free seawater) regions plays a key role in particle growth events that shape the aerosol size distributions observed at Alert (82.5 ∘ N, 62.3 ∘ W), Eureka (80.1 ∘ N, 86.4 ∘ W), and along a NETCARE ship track within the Archipelago. We refer to this SOA as Arctic marine SOA (AMSOA) to reflect the Arctic marine-based and likely biogenic sources for the precursors of the condensing organic vapors. AMSOA from a simulated flux (500 <math xmlns="http://www.w3.org/1998/Math/MathML" id="M5" display="inline" overflow="scroll" dspmath="mathml"><mrow class="unit"><mi mathvariant="normal">µ</mi><mi mathvariant="normal">g</mi><mspace linebreak="nobreak" width="0.125em"/><msup><mi mathvariant="normal">m</mi><mrow><mo>-</mo><mn mathvariant="normal">2</mn></mrow></msup><mspace linebreak="nobreak" width="0.125em"/><msup><mi mathvariant="normal">day</mi><mrow><mo>-</mo><mn mathvariant="normal">1</mn></mrow></msup></mrow></math> <svg:svg xmlns:svg="http://www.w3.org/2000/svg" width="64pt" height="15pt" class="svg-formula" dspmath="mathimg" md5hash="8f93b7fde00f18c6b1eb9f6df658301c"><svg:image xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="acp-19-2787-2019-ie00001.svg" width="64pt" height="15pt" src="acp-19-2787-2019-ie00001.png"/></svg:svg> , north of 50 ∘ N) of precursor vapors (with an assumed yield of unity) reduces the summertime particle size distribution model–observation mean fractional error 2- to 4-fold, relative to a simulation without this AMSOA. Particle growth due to the condensable organic vapor flux contributes strongly (30 %–50 %) to the simulated summertime-mean number of particles with diameters larger than 20 nm in the study region. This growth couples with ternary particle nucleation (sulfuric acid, ammonia, and water vapor) and biogenic sulfate condensation to account for more than 90 % of this simulated particle number, which represents a strong biogenic influence. The simulated fit to summertime size-distribution observations is further improved at Eureka and for the ship track by scaling up the nucleation rate by a factor of 100 to account for other particle precursors such as gas-phase iodine and/or amines and/or fragmenting primary particles that could be missing from our simulations. Additionally, the fits to the observed size distributions and total aerosol number concentrations for particles larger than 4 nm improve with the assumption that the AMSOA contains semi-volatile species: the model–observation mean fractional error is reduced 2- to 3-fold for the Alert and ship track size distributions. AMSOA accounts for about half of the simulated particle surface area and volume distributions in the summertime Canadian Arctic Archipelago, with climate-relevant simulated summertime pan-Arctic-mean top-of-the-atmosphere aerosol direct ( −0.04 W m −2 ) and cloud-albedo indirect ( −0.4 W m −2 ) radiative effects, which due to uncertainties are viewed as an order of magnitude estimate. Future work should focus on further understanding summertime Arctic sources of AMSOA. Text albedo Arctic Archipelago Arctic Canadian Arctic Archipelago Copernicus Publications: E-Journals Arctic Canadian Arctic Archipelago Eureka ENVELOPE(-85.940,-85.940,79.990,79.990) Atmospheric Chemistry and Physics 19 5 2787 2812

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