Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis

Volcanic particulate matter (PM), whether emitted directly as ash or indirectly via suspension of glaciogenic sediments, comprises a large fraction of atmospheric PM in Iceland, a major high-latitude dust source area. This PM leads to direct reductions in air quality and health; in addition, because...

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Bibliographic Details
Main Authors: Maya Abou-Ghanem (6401174), Britta J. L. Jensen (11575199), Sarah A. Styler (761541), Manolis N. Romanias (1757788)
Format: Dataset
Language:unknown
Published: 2021
Subjects:
Biophysics
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
trace pollutant gases
predicted mineral phases
powerful semiconductor photocatalyst
icelandic volcanic dust
major dust events
indirectly via suspension
state surface area
reaction proceeds via
bet </ sub
volcanic pm would
volcanic pm
indirectly influence
pm leads
atmospheric pm
water vapor
results highlight
relatively modest
relative humidity
phase ozone
ozone chemistry
olivine )
major high
large fraction
help resolve
ground surface
glass fraction
glaciogenic sediments
direct reductions
competitive adsorbate
chemical composition
atmospheric reactivity
apparent contradiction
air quality
Langmuir
Iceland
Online Access:https://doi.org/10.1021/acsearthspacechem.0c00363.s002
id ftsmithonian:oai:figshare.com:article/16825220
record_format openpolar
spelling ftsmithonian:oai:figshare.com:article/16825220 2023-05-15T16:50:01+02:00 Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis Maya Abou-Ghanem (6401174) Britta J. L. Jensen (11575199) Sarah A. Styler (761541) Manolis N. Romanias (1757788) 2021-10-18T00:00:00Z https://doi.org/10.1021/acsearthspacechem.0c00363.s002 unknown https://figshare.com/articles/dataset/Ozone_Chemistry_and_Photochemistry_at_the_Surface_of_Icelandic_Volcanic_Dust_Insights_from_Elemental_Speciation_Analysis/16825220 doi:10.1021/acsearthspacechem.0c00363.s002 CC BY-NC 4.0 CC-BY-NC Biophysics Environmental Sciences not elsewhere classified Biological Sciences not elsewhere classified Chemical Sciences not elsewhere classified trace pollutant gases predicted mineral phases powerful semiconductor photocatalyst icelandic volcanic dust major dust events indirectly via suspension state surface area reaction proceeds via bet </ sub volcanic pm would volcanic pm indirectly influence pm leads atmospheric pm water vapor results highlight relatively modest relative humidity phase ozone ozone chemistry olivine ) major high large fraction help resolve ground surface glass fraction glaciogenic sediments direct reductions competitive adsorbate chemical composition atmospheric reactivity apparent contradiction air quality Dataset 2021 ftsmithonian https://doi.org/10.1021/acsearthspacechem.0c00363.s002 2021-12-20T00:02:24Z Volcanic particulate matter (PM), whether emitted directly as ash or indirectly via suspension of glaciogenic sediments, comprises a large fraction of atmospheric PM in Iceland, a major high-latitude dust source area. This PM leads to direct reductions in air quality and health; in addition, because it provides a surface for reactions with trace pollutant gases, it also has the potential to indirectly influence the chemical composition of the troposphere. Here, we investigate the reaction of gas-phase ozone with a volcanic dust sample obtained from the Mýrdalssandur source region in southern Iceland. We find that the steady-state surface area-scaled ozone uptake coefficient (γ BET ) for this sample decreases with increasing ozone mixing ratio and relative humidity, which implies that the reaction proceeds via a Langmuir–Hinshelwood mechanism with water vapor as competitive adsorbate. Using the γ BET values we obtain here, we conclude that the ozone flux to volcanic PM would be <10% of its flux to the ground surface under typical Icelandic weather conditions, even during major dust events. Interestingly, although the Mýrdalssandur dust sample is high in elemental Ti, which in its anatase and rutile forms is a powerful semiconductor photocatalyst, its photochemistry is relatively modest. We use electron microprobe analysis to help resolve this apparent contradiction: in particular, we show that the bulk of the Ti in this sample is present in its glass fraction, with the remainder present not as anatase or rutile but rather in other predicted mineral phases (pyroxene, plagioclase, ilmenite, titanomagnetite, and olivine). These results highlight the advantages of using elemental speciation analysis to understand the atmospheric reactivity of volcanic PM. Dataset Iceland Unknown Langmuir ENVELOPE(-67.150,-67.150,-66.967,-66.967)
institution Open Polar
collection Unknown
op_collection_id ftsmithonian
language unknown
topic Biophysics
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
trace pollutant gases
predicted mineral phases
powerful semiconductor photocatalyst
icelandic volcanic dust
major dust events
indirectly via suspension
state surface area
reaction proceeds via
bet </ sub
volcanic pm would
volcanic pm
indirectly influence
pm leads
atmospheric pm
water vapor
results highlight
relatively modest
relative humidity
phase ozone
ozone chemistry
olivine )
major high
large fraction
help resolve
ground surface
glass fraction
glaciogenic sediments
direct reductions
competitive adsorbate
chemical composition
atmospheric reactivity
apparent contradiction
air quality
spellingShingle Biophysics
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
trace pollutant gases
predicted mineral phases
powerful semiconductor photocatalyst
icelandic volcanic dust
major dust events
indirectly via suspension
state surface area
reaction proceeds via
bet </ sub
volcanic pm would
volcanic pm
indirectly influence
pm leads
atmospheric pm
water vapor
results highlight
relatively modest
relative humidity
phase ozone
ozone chemistry
olivine )
major high
large fraction
help resolve
ground surface
glass fraction
glaciogenic sediments
direct reductions
competitive adsorbate
chemical composition
atmospheric reactivity
apparent contradiction
air quality
Maya Abou-Ghanem (6401174)
Britta J. L. Jensen (11575199)
Sarah A. Styler (761541)
Manolis N. Romanias (1757788)
Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis
topic_facet Biophysics
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
trace pollutant gases
predicted mineral phases
powerful semiconductor photocatalyst
icelandic volcanic dust
major dust events
indirectly via suspension
state surface area
reaction proceeds via
bet </ sub
volcanic pm would
volcanic pm
indirectly influence
pm leads
atmospheric pm
water vapor
results highlight
relatively modest
relative humidity
phase ozone
ozone chemistry
olivine )
major high
large fraction
help resolve
ground surface
glass fraction
glaciogenic sediments
direct reductions
competitive adsorbate
chemical composition
atmospheric reactivity
apparent contradiction
air quality
description Volcanic particulate matter (PM), whether emitted directly as ash or indirectly via suspension of glaciogenic sediments, comprises a large fraction of atmospheric PM in Iceland, a major high-latitude dust source area. This PM leads to direct reductions in air quality and health; in addition, because it provides a surface for reactions with trace pollutant gases, it also has the potential to indirectly influence the chemical composition of the troposphere. Here, we investigate the reaction of gas-phase ozone with a volcanic dust sample obtained from the Mýrdalssandur source region in southern Iceland. We find that the steady-state surface area-scaled ozone uptake coefficient (γ BET ) for this sample decreases with increasing ozone mixing ratio and relative humidity, which implies that the reaction proceeds via a Langmuir–Hinshelwood mechanism with water vapor as competitive adsorbate. Using the γ BET values we obtain here, we conclude that the ozone flux to volcanic PM would be <10% of its flux to the ground surface under typical Icelandic weather conditions, even during major dust events. Interestingly, although the Mýrdalssandur dust sample is high in elemental Ti, which in its anatase and rutile forms is a powerful semiconductor photocatalyst, its photochemistry is relatively modest. We use electron microprobe analysis to help resolve this apparent contradiction: in particular, we show that the bulk of the Ti in this sample is present in its glass fraction, with the remainder present not as anatase or rutile but rather in other predicted mineral phases (pyroxene, plagioclase, ilmenite, titanomagnetite, and olivine). These results highlight the advantages of using elemental speciation analysis to understand the atmospheric reactivity of volcanic PM.
format Dataset
author Maya Abou-Ghanem (6401174)
Britta J. L. Jensen (11575199)
Sarah A. Styler (761541)
Manolis N. Romanias (1757788)
author_facet Maya Abou-Ghanem (6401174)
Britta J. L. Jensen (11575199)
Sarah A. Styler (761541)
Manolis N. Romanias (1757788)
author_sort Maya Abou-Ghanem (6401174)
title Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis
title_short Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis
title_full Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis
title_fullStr Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis
title_full_unstemmed Ozone Chemistry and Photochemistry at the Surface of Icelandic Volcanic Dust: Insights from Elemental Speciation Analysis
title_sort ozone chemistry and photochemistry at the surface of icelandic volcanic dust: insights from elemental speciation analysis
publishDate 2021
url https://doi.org/10.1021/acsearthspacechem.0c00363.s002
long_lat ENVELOPE(-67.150,-67.150,-66.967,-66.967)
geographic Langmuir
geographic_facet Langmuir
genre Iceland
genre_facet Iceland
op_relation https://figshare.com/articles/dataset/Ozone_Chemistry_and_Photochemistry_at_the_Surface_of_Icelandic_Volcanic_Dust_Insights_from_Elemental_Speciation_Analysis/16825220
doi:10.1021/acsearthspacechem.0c00363.s002
op_rights CC BY-NC 4.0
op_rightsnorm CC-BY-NC
op_doi https://doi.org/10.1021/acsearthspacechem.0c00363.s002
_version_ 1766040200838905856

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