Global simulations of the impact on contemporary climate of a perturbation to the sea-to-air flux of dimethylsulfide

Gabric, Albert Jerome; Qu, Bo; Rotstayn, Leon; Shephard, Jill M.

doi:10.22499/2.6303.002

Cited by 26 publications

(30 citation statements)

References 75 publications

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“…Furthermore, the sign and strength of feedback loops involving different phytoplankton groups varies. The overall sign of the feedback disagrees with some previous studies (Bopp et al 2004;Gunson et al 2006;Gabric et al 2013). This discrepancy can be attributed to the coupling between a dynamic marine ecosystem module and the sulfur cycle mechanism adopted in the current simulations.…”

Section: Discussioncontrasting

confidence: 99%

“…They found negligible changes in the direct effect and an indirect effect of -0.05 W/m 2 . Using the elevated DMS flux simulated by Gabric et al (2004) (3 9 CO 2 ), Gabric et al (2013) estimated the global mean direct effect due to the DMS perturbation to be -0.05 W/m 2 and the total radiative forcing to be -0.48 W/m 2 . Sensitivity simulations conducted by Gunson et al (2006) showed significant impacts on the net cloud radiative forcing of -2 and 3 W/m 2 due to doubling and halving the DMS flux, respectively.…”

Section: Introductionmentioning

confidence: 99%

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Influence of dimethyl sulfide on the carbon cycle and biological production

et al. 2018

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Dimethyl sulfide (DMS) is a significant source of marine sulfate aerosol and plays an important role in modifying cloud properties. Fully coupled climate simulations using dynamic marine ecosystem and DMS calculations are conducted to estimate DMS fluxes under various climate scenarios and to examine the sign and strength of phytoplankton-DMS-climate feedbacks for the first time. Simulation results show small differences in the DMS production and emissions between pre-industrial and present climate scenarios, except for some areas in the Southern Ocean. There are clear changes in surface ocean DMS concentrations moving into the future, and they are attributable to changes in phytoplankton production and competition driven by complex spatially varying mechanisms. Comparisons between parallel simulations with and without DMS fluxes into the atmosphere show significant differences in marine ecosystems and physical fields. Without DMS, the missing subsequent aerosol indirect effects on clouds and radiative forcing lead to fewer clouds, more solar radiation, and a much warmer climate. Phaeocystis, a uniquely efficient organosulfur producer with a growth advantage under cooler climate states, can benefit from producing the compound through cooling effects of DMS in the climate system. Our results show a tight coupling between the sulfur and carbon cycles. The ocean carbon uptake declines without DMS emissions to the atmosphere. The analysis indicates a weak positive phytoplankton-DMS-climate feedback at the global scale, with large spatial variations driven by individual autotrophic functional groups and complex mechanisms. The sign and strength of the feedback vary with climate states and phytoplankton groups. This highlights the importance of a dynamic marine ecosystem module and the sulfur cycle mechanism in climate projections.

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Section: Discussioncontrasting

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Influence of dimethyl sulfide on the carbon cycle and biological production

et al. 2018

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“…Thomas et al (2011) showed 23.1% changes in aerosol optical depth (AOD) between simulations with and without oceanic DMS emissions over 30°S-75°S using a global aerosol-chemistry-cloud microphysics-climate model (ECHAM5-HAMMOZ). Another previous study suggested a weaker response of AOD to DMS perturbations, a 3.5% increase in AOD in response to a 14% increase in the oceanic sulfur emission (Gabric et al, 2013). Motivated by these studies, we compare modeled AOD to examine the sensitivity of direct effects to changes in ocean ecosystems through the sulfur cycle.…”

Section: Aerosol Optical Depthmentioning

confidence: 96%

Impacts of Shifts in Phytoplankton Community on Clouds and Climate via the Sulfur Cycle

Wang

Maltrud

Burrows

et al. 2018

Global Biogeochemical Cycles

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Dimethyl sulfide (DMS), primarily produced by marine organisms, contributes significantly to sulfate aerosol loading over the ocean after being oxidized in the atmosphere. In addition to exerting a direct radiative effect, the resulting aerosol particles act as cloud condensation nuclei, modulating cloud properties and extent, with impacts on atmospheric radiative transfer and climate. Thus, changes in pelagic ecosystems, such as phytoplankton physiology and community structure, may influence organosulfur production, and subsequently affect climate via the sulfur cycle. A fully coupled Earth system model, including explicit marine ecosystems and the sulfur cycle, is used here to investigate the impacts of changes associated with individual phytoplankton groups on DMS emissions and climate. Simulations show that changes in phytoplankton community structure, DMS production efficiency, and interactions of multielement biogeochemical cycles can all lead to significant differences in DMS transfer to the atmosphere. Subsequent changes in sulfate aerosol burden, cloud condensation nuclei number, and radiative effect are examined. We find the global annual mean cloud radiative effect shifts up to 0.21 W/m2, and the mean surface temperature increases up to 0.1 °C due to DMS production changes associated with individual phytoplankton group in simulations with radiative effects at the 2,100 levels under an 8.5 scenario. However, changes in DMS emissions, radiative effect, and surface temperature are more intensive on regional scales. Hence, we speculate that major uncertainties associated with future marine sulfur cycling will involve strong region‐to‐region climate shifts. Further understanding of marine ecosystems and the relevant phytoplankton‐aerosol‐climate linkage are needed for improving climate projections.

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“…The oceanic CO 2 absorption capacity decreases, while oceanic CO 2 burden increases. Gabric et al (2013) used an atmospheric GCM with incorporated sulfur cycle, coupled to a mixed-layer ("q-flux") ocean, to estimate the climatic response to a prescribed meridionally variable change in zonal DMS flux. It is not well known that on the other hand, atmospheric aerosols have a cooling effect on global temperature.…”

Section: Global Warming or Cooling?mentioning

confidence: 99%

The Impact of Melting Ice on the Ecosystems in Greenland Sea

Qu¹

2015

SpringerBriefs in Environmental Science

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Global simulations of the impact on contemporary climate of a perturbation to the sea-to-air flux of dimethylsulfide

Cited by 26 publications

References 75 publications

Influence of dimethyl sulfide on the carbon cycle and biological production

Influence of dimethyl sulfide on the carbon cycle and biological production

Impacts of Shifts in Phytoplankton Community on Clouds and Climate via the Sulfur Cycle

The Impact of Melting Ice on the Ecosystems in Greenland Sea

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