Climate change impacts on natural sulfur production: Ocean acidification and community shifts

Zachary M. Menzo; Scott Elliott; Corinne A. Hartin; Forrest M. Hoffman; Shanlin Wang

doi:10.3390/atmos9050167

Climate change impacts on natural sulfur production: Ocean acidification and community shifts

Zachary M. Menzo, Scott Elliott, Corinne A. Hartin, Forrest M. Hoffman, Shanlin Wang

Computational Earth Sciences Group

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

Utilizing the reduced-complexity model Hector, a regional scale analysis was conducted quantifying the possible effects climate change may have on dimethyl sulfide (DMS) emissions within the oceans. The investigation began with a review of the sulfur cycle in modern Earth system models. We then expanded the biogeochemical representation within Hector to include a natural ocean component while accounting for acidification and planktonic community shifts. The report presents results from both a latitudinal and a global perspective. This new approach highlights disparate outcomes which have been inadequately characterized via planetary averages in past publications. Our findings suggest that natural sulfur emissions (ESN) may exert a forcing up to 4 times that of the CO₂ marine feedback, 0.62 and 0.15 Wm^-2, respectively, and reverse the radiative forcing sign in low latitudes. Additionally, sensitivity tests were conducted to demonstrate the need for further examination of the DMS loop. Ultimately, the present work attempts to include dynamic ESN within reduced-complexity simulations of the sulfur cycle, illustrating its impact on the global radiative budget.

Original language	English
Article number	167
Journal	Atmosphere
Volume	9
Issue number	5
DOIs	https://doi.org/10.3390/atmos9050167
State	Published - May 1 2018

Funding

Acknowledgments: Authors of this publication thank JGCRI for their time and expertise as we implemented the simple climate model. This research was supported through the Reducing Uncertainties in Biogeochemical Interactions through Synthesis and Computation (RUBISCO) and High Latitude (HiLAT) Scientific Focus Areas, which are sponsored by the Regional & Global Climate Modeling (RGCM) Program in the Climate and Environmental Sciences Division (CESD) of the Biological and Environmental Research (BER) Program in the U.S. Department of Energy Office of Science.

Keywords

Climate change
Community shifts
Dimethyl sulfide
Marine biogeochemical feedback
Ocean acidification
Phaeocystis
Phytoplankton

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title = "Climate change impacts on natural sulfur production: Ocean acidification and community shifts",

abstract = "Utilizing the reduced-complexity model Hector, a regional scale analysis was conducted quantifying the possible effects climate change may have on dimethyl sulfide (DMS) emissions within the oceans. The investigation began with a review of the sulfur cycle in modern Earth system models. We then expanded the biogeochemical representation within Hector to include a natural ocean component while accounting for acidification and planktonic community shifts. The report presents results from both a latitudinal and a global perspective. This new approach highlights disparate outcomes which have been inadequately characterized via planetary averages in past publications. Our findings suggest that natural sulfur emissions (ESN) may exert a forcing up to 4 times that of the CO2 marine feedback, 0.62 and 0.15 Wm-2, respectively, and reverse the radiative forcing sign in low latitudes. Additionally, sensitivity tests were conducted to demonstrate the need for further examination of the DMS loop. Ultimately, the present work attempts to include dynamic ESN within reduced-complexity simulations of the sulfur cycle, illustrating its impact on the global radiative budget.",

keywords = "Climate change, Community shifts, Dimethyl sulfide, Marine biogeochemical feedback, Ocean acidification, Phaeocystis, Phytoplankton",

author = "Menzo, {Zachary M.} and Scott Elliott and Hartin, {Corinne A.} and Hoffman, {Forrest M.} and Shanlin Wang",

note = "Publisher Copyright: {\textcopyright} 2018 by the authors.",

year = "2018",

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doi = "10.3390/atmos9050167",

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T2 - Ocean acidification and community shifts

AU - Menzo, Zachary M.

AU - Elliott, Scott

AU - Hartin, Corinne A.

AU - Hoffman, Forrest M.

AU - Wang, Shanlin

PY - 2018/5/1

Y1 - 2018/5/1

N2 - Utilizing the reduced-complexity model Hector, a regional scale analysis was conducted quantifying the possible effects climate change may have on dimethyl sulfide (DMS) emissions within the oceans. The investigation began with a review of the sulfur cycle in modern Earth system models. We then expanded the biogeochemical representation within Hector to include a natural ocean component while accounting for acidification and planktonic community shifts. The report presents results from both a latitudinal and a global perspective. This new approach highlights disparate outcomes which have been inadequately characterized via planetary averages in past publications. Our findings suggest that natural sulfur emissions (ESN) may exert a forcing up to 4 times that of the CO2 marine feedback, 0.62 and 0.15 Wm-2, respectively, and reverse the radiative forcing sign in low latitudes. Additionally, sensitivity tests were conducted to demonstrate the need for further examination of the DMS loop. Ultimately, the present work attempts to include dynamic ESN within reduced-complexity simulations of the sulfur cycle, illustrating its impact on the global radiative budget.

AB - Utilizing the reduced-complexity model Hector, a regional scale analysis was conducted quantifying the possible effects climate change may have on dimethyl sulfide (DMS) emissions within the oceans. The investigation began with a review of the sulfur cycle in modern Earth system models. We then expanded the biogeochemical representation within Hector to include a natural ocean component while accounting for acidification and planktonic community shifts. The report presents results from both a latitudinal and a global perspective. This new approach highlights disparate outcomes which have been inadequately characterized via planetary averages in past publications. Our findings suggest that natural sulfur emissions (ESN) may exert a forcing up to 4 times that of the CO2 marine feedback, 0.62 and 0.15 Wm-2, respectively, and reverse the radiative forcing sign in low latitudes. Additionally, sensitivity tests were conducted to demonstrate the need for further examination of the DMS loop. Ultimately, the present work attempts to include dynamic ESN within reduced-complexity simulations of the sulfur cycle, illustrating its impact on the global radiative budget.

KW - Climate change

KW - Community shifts

KW - Dimethyl sulfide

KW - Marine biogeochemical feedback

KW - Ocean acidification

KW - Phaeocystis

KW - Phytoplankton

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VL - 9

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ER -

Climate change impacts on natural sulfur production: Ocean acidification and community shifts

Abstract

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Keywords

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