Amplification of global warming through pH dependence of DMS production simulated with a fully coupled Earth system model

Schwinger, Jörg; Tjiputra, Jerry; Goris, Nadine; Six, Katharina; Kirkevåg, Alf; Seland, Øyvind; Heinze, Christoph; Ilyina, Tatiana

doi:10.5194/bg-14-3633-2017

Cited by 42 publications

(55 citation statements)

References 40 publications

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“…Culture experiments have confirmed that DMSP and DMS cell contents (normalized to cell volume) can be reduced by about 3 and 10 times in a dominant coccolithophorid species, Emiliania huxleyi, when exposed to doubled atmospheric CO 2 concentrations (Avgoustidi et al, 2012). In CALC, we reduced coccolithophore cellular organosulfur content in the DMS module by 90% for the high CO 2 scenario to provide a potential upper bound of the impact of ocean acidification on DMS production and compare with previous simulations by Six et al (2013) and Schwinger et al (2017). Simulated differences in DMS concentrations and other fields represent the consequences of an acidification-induced decline in ocean DMS production by coccolithophores.…”

Section: Ocean Acidification Simulation (Calc)supporting

confidence: 60%

“…This is mostly attributable to different configurations of our simulations from Six et al (2013) as discussed previously, as well as missing feedback in the uncoupled simulations in Six et al (2013). Similarly, our simulated changes in radiative effect and temperature in CALC are smaller than results from Schwinger et al (2017), which suggested 0.19-0.30 W/m 2 changes of…”

Section: Climate Change Due To Biogenic Sulfur Emission Changesmentioning

confidence: 47%

“…This reduction in DMS emissions is much smaller than estimates in Six et al (2013) and Schwinger et al (2017), which suggested an additional reduction of 5%-17% and 17%-27%, respectively, depending on the prescribed sensitivity relationships. This is because Six et al (2013) and Schwinger et al (2017) applied empirical relationships between pH and the total DMS production, while we assume that only the DMS production attributable to calcifiers changes due to acidification. Our CALC simulation likely underestimates the total impact of ocean acidification on DMS production because of we limited our scope to the impacts of calcifying organisms.…”

Section: Changes To Dms Concentrations and Emissionsmentioning

confidence: 65%

“…Mesocosm and laboratory experiments suggested that increasing acidity might lead to decreasing DMS concentrations Avgoustidi et al, 2012;Hopkins et al, 2010). Six et al (2013) and Schwinger et al (2017) suggested that decreases in DMS emissions resulting from ocean acidification might strongly amplify global warming. Given various potential changes in marine ecosystems, the DMS production will likely be affected.…”

Section: Introductionmentioning

confidence: 99%

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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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Section: Ocean Acidification Simulation (Calc)supporting

confidence: 60%

Section: Climate Change Due To Biogenic Sulfur Emission Changesmentioning

confidence: 47%

Section: Changes To Dms Concentrations and Emissionsmentioning

confidence: 65%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

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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“…2.4), hence allowing for a direct biogeochemical climate feedback in coupled simulations. The DMS air-sea flux is simulated as a function of upper-ocean biological production following the formulation of Six and Maier-Reimer (1996) and 135 was first tested in the NorESM model framework by Schwinger et al (2017).…”

Section: Introductionmentioning

confidence: 99%

The Norwegian Earth System Model, NorESM2 – Evaluation of theCMIP6 DECK and historical simulations

Seland

Bentsen

Graff

et al. 2020

Preprint

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The second version of the fully coupled Norwegian Earth System Model (NorESM2) is presented and evaluated.NorESM2 is based on the second version of the Community Earth System Model (CESM2), but has entirely different ocean and ocean biogeochemistry models; a new module for aerosols in the atmosphere model along with aerosol-radiation-cloud interactions and changes related to the moist energy formulation, deep convection scheme and angular momentum conservation; modified albedo and air-sea turbulent flux calculations; and minor changes to land and sea ice models. We show results 5 from low (∼2 • ) and medium (∼1 • ) atmosphere-land resolution versions of NorESM2 that have both been used to carry out simulations for the sixth phase of the Coupled Model Intercomparison Project (CMIP6). The stability of the pre-industrial climate and the sensitivity of the model to abrupt and gradual quadrupling of CO 2 is assessed, along with the ability of the model to simulate the historical climate under the CMIP6 forcings. As compared to observations and reanalyses, NorESM2represents an improvement over previous versions of NorESM in most aspects. NorESM2 is less sensitive to greenhouse gas 10 forcing than its predecessors, with an equilibrium climate sensitivity of 2.5 K in both resolutions on a 150 year frame. We also consider the model response to future scenarios as defined by selected shared socioeconomic pathways (SSPs) from the Scenario Model Intercomparison Project defined under CMIP6. Under the four scenarios SSP1-2.6, SSP2-4.5, SSP3-7.0, and SSP5-8.5, the warming in the period 2090-2099 compared to 1850-1879 reaches 1.3, 2.2, 3.0, and 3.9 K in NorESM2-LM, and 1.3, 2.1, 3.1, and 3.9 K in NorESM-MM, robustly similar in both resolutions. NorESM2-LM shows a rather satisfactorily 15 evolution of recent sea ice area. In NorESM2-LM an ice free Arctic Ocean is only avoided in the SSP1-2.6 scenario. 30 harmonizing the implementation of the aerosol scheme with the standard aerosol schemes in CESM. To extend the capabilities of NorESM as an Earth System Model, a strong focus has been put on the interactive description of natural emissions of aerosols and their precursors, and tightening the coupling between the different Earth System components. Finally, the ocean model (Bentsen et al., in prep.) and the ocean biogeochemistry module (Schwinger et al., 2016; Tjiputra et al., 2019) have been further developed. 35 This manuscript gives a description of NorESM2, and a basic evaluation against observations of the simulation of the atmosphere, sea ice, and ocean in a small set of baseline long-duration experiments with the new model. It focuses on such aspects as the simulated climatology, its stability and internal variability, and also on its response under historical and enhancedgreenhouse gas scenario forcings. Currently, NorESM2 exists in three versions. The two versions presented here are NorESM2-LM and NorESM2-MM: they 40 differ in the horizontal resolution of the atmosphere and land component (approximately 2 • for LM and 1 • i...

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Climate Change with Its Impacts on Soil and Soil Microbiome Regulating Biogeochemical Nutrient Transformations

2021

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Amplification of global warming through pH dependence of DMS production simulated with a fully coupled Earth system model

Cited by 42 publications

References 40 publications

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

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

The Norwegian Earth System Model, NorESM2 – Evaluation of theCMIP6 DECK and historical simulations

Climate Change with Its Impacts on Soil and Soil Microbiome Regulating Biogeochemical Nutrient Transformations

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