Atmospheric processing of iron in mineral and combustion aerosols: development of an intermediate-complexity mechanism suitable for Earth system models
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Published:2018-10-05
Issue:19
Volume:18
Page:14175-14196
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ISSN:1680-7324
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Container-title:Atmospheric Chemistry and Physics
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language:en
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Short-container-title:Atmos. Chem. Phys.
Author:
Scanza Rachel A., Hamilton Douglas S.ORCID, Perez Garcia-Pando CarlosORCID, Buck Clifton, Baker AlexORCID, Mahowald Natalie M.
Abstract
Abstract. Atmospheric processing of iron in dust and combustion aerosols is simulated using an
intermediate-complexity soluble iron mechanism designed for Earth system
models. The solubilization mechanism includes both a dependence on aerosol
water pH and in-cloud oxalic acid. The simulations of size-resolved total,
soluble and fractional iron solubility indicate that this mechanism captures
many but not all of the features seen from cruise observations of labile
iron. The primary objective was to determine the extent to which our
solubility scheme could adequately match observations of fractional iron
solubility. We define a semi-quantitative metric as the model mean at points
with observations divided by the observational mean (MMO). The model is in
reasonable agreement with observations of fractional iron solubility with an
MMO of 0.86. Several sensitivity studies are performed to ascertain the
degree of complexity needed to match observations; including the oxalic acid
enhancement is necessary, while different parameterizations for calculating
model oxalate concentrations are less important. The percent change in
soluble iron deposition between the reference case (REF) and the simulation
with acidic processing alone is 63.8 %, which is consistent with previous
studies. Upon deposition to global oceans, global mean combustion iron
solubility to total fractional iron solubility is 8.2 %; however, the
contribution of fractional iron solubility from combustion sources to ocean
basins below 15∘ S is approximately 50 %. We conclude that, in
many remote ocean regions, sources of iron from combustion and dust aerosols
are equally important. Our estimates of changes in deposition of soluble iron
to the ocean since preindustrial climate conditions suggest roughly a doubling due to a combination of
higher dust and combustion iron emissions along with more efficient
atmospheric processing.
Funder
U.S. Department of Energy National Science Foundation
Publisher
Copernicus GmbH
Subject
Atmospheric Science
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