Assessing the potential efficacy of marine cloud brightening for cooling Earth using a simple heuristic model

Wood, Robert

doi:10.5194/acp-21-14507-2021

Cited by 50 publications

(63 citation statements)

References 96 publications

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“…Based on theoretical analyses from previous studies (e.g., Diamond et al, 2020;Wood, 2021), we decomposed the contributions of the Twomey effect and cloud adjustments to albedo and SW CRE. For both the L06 and L10 cases an increase in aerosols relative to the baseline case leads to an increase in the SW CRE due to the Twomey effect.…”

Section: Discussionmentioning

confidence: 99%

Simulating Aerosol Lifecycle Impacts on the Subtropical Stratocumulus‐to‐Cumulus Transition Using Large‐Eddy Simulations

et al. 2022

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Observed stratocumulus to cumulus transitions (SCTs) and their sensitivity to aerosols are studied using a large‐eddy simulation (LES) model that simulates the aerosol lifecycle, including aerosol sources and sinks. To initialize, force, and evaluate the LES, we used a combination of reanalysis, satellite, and aircraft data from the 2015 Cloud System Evolution in the Trades field campaign over the Northeast Pacific. The simulations follow two Lagrangian trajectories from initially overcast stratocumulus (Sc) to the tropical shallow cumulus region near Hawaii. The first trajectory is characterized by an initially clean, well‐mixed Sc‐topped marine boundary layer (MBL), then continuous MBL deepening and precipitation onset followed by a clear SCT and a consistent reduction of aerosols that ultimately leads to an ultra‐clean layer in the upper MBL. The second trajectory is characterized by an initially polluted and decoupled MBL, weak precipitation, and a late SCT. Overall, the LES simulates the observed general MBL features. Sensitivity studies with different aerosol initial and boundary conditions reveal aerosol‐induced changes in the transition, and albedo changes are decomposed into the Twomey effect and adjustments of cloud liquid water path and cloud fraction. Impacts on precipitation play a key role in the sensitivity to aerosols: for the first case, runs with enhanced aerosols exhibit distinct changes in microphysics and macrophysics such as enhanced cloud droplet number concentration, reduced precipitation, and delayed SCT. Cloud adjustments are dominant in this case. For the second case, enhancing aerosols does not affect cloud macrophysical properties significantly, and the Twomey effect dominates.

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Section: Discussionmentioning

confidence: 99%

Simulating Aerosol Lifecycle Impacts on the Subtropical Stratocumulus‐to‐Cumulus Transition Using Large‐Eddy Simulations

et al. 2022

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“…The present study is designed to uniquely examine the TOA shortwave radiative response of MCB and MSB in the Gulf of Mexico; nonetheless it is useful to compare these results with those of Wood (2021) and other studies (e.g., Ahlm et al, 2017;Alterskjaer et al, 2012;Latham et al, 2008;Stjern et al, 2018) that show that MCB can be employed to offset the radiative forcing consistent with a doubling of CO 2 (2xCO 2 ) from the pre-industrial level (3.7 W m −2 , Ramaswamy et al, 2001). Specifically, Wood (2021) details a pathway to offset the global 2xCO 2 forcing that requires about 9% of the ocean to be seeded with Aitken mode particles to achieve a seven-fold increase in CDNC in the perturbed clouds and a corresponding increase in cloud albedo of 0.16.…”

Section: Caveats and Comparisonsmentioning

confidence: 99%

“…Previous studies show that the radiative perturbations from sea salt injection are sensitive to the mean diameter of the injected particles as well as the amount (e.g., Connolly et al, 2014;Partanen et al, 2012;Wood, 2021). To evaluate the diameter sensitivity, we design four experiments to compare to a control simulation (CTRL), one in which the additional sea salt flux contains Aitken mode particles (with a diameter distribution between 39 and 156 nm, EXP_AIT), one with accumulation mode particles (between 156 and 625 nm, EXP_ACC), one with large accumulation mode particles (between 625-2,500 nm, EXP_ACC_LG), and one with coarse mode particles (between 2,500-10,000 nm, EXP_COARSE).…”

Section: Control Simulation and Experimental Designmentioning

confidence: 99%

“…Collectively, these studies show the potential of MCB to offset, in full or partial, the global mean radiative forcing consistent with a doubling of CO 2 from the pre-industrial levels (3.7 W m −2 , Ramaswamy et al, 2001). Wood (2021) details multiple pathways to offset the radiative forcing from a doubling of CO 2 levels by deriving an equation that is a function of the fraction of ocean to be seeded, the unperturbed cloud albedo, the change in cloud albedo, and the ratio of cloud droplet number concentration (CDNC) between the perturbed and unperturbed clouds. Wood (2021) discusses a scenario involving seeding the full fraction of the ocean where low clouds are present and are approximately 1,000 km away from land (about 18% of the ocean surface) to achieve a CDNC ratio of about 3 and a change in cloud albedo of about 0.09, with respect to an unperturbed cloud with an albedo of 0.50.…”

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confidence: 99%

“…Wood (2021) details multiple pathways to offset the radiative forcing from a doubling of CO 2 levels by deriving an equation that is a function of the fraction of ocean to be seeded, the unperturbed cloud albedo, the change in cloud albedo, and the ratio of cloud droplet number concentration (CDNC) between the perturbed and unperturbed clouds. Wood (2021) discusses a scenario involving seeding the full fraction of the ocean where low clouds are present and are approximately 1,000 km away from land (about 18% of the ocean surface) to achieve a CDNC ratio of about 3 and a change in cloud albedo of about 0.09, with respect to an unperturbed cloud with an albedo of 0.50. Seeding only half of this ocean area requires the CDNC ratio to be about 7 and a change in cloud albedo of about 0.16, with respect to an unperturbed cloud with an albedo of 0.50.…”

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The Shortwave Radiative Flux Response to an Injection of Sea Salt Aerosols in the Gulf of Mexico

et al. 2022

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As climate change progresses and continues to cause increased risks and damages to society, there are increasing discussions focused on solar geoengineering as a means of temporarily and deliberately reducing some of the impacts of human-caused greenhouse gas emissions (NASEM, 2021). Marine cloud brightening (MCB; Latham, 1990) has emerged as one of the more commonly discussed ideas. This idea involves taking advantage of aerosol-cloud interactions (Haywood & Boucher, 2000): injecting sea salt aerosols into marine low clouds can, under certain meteorological conditions, cause their albedo to increase (Twomey, 1974(Twomey, , 1977, which would cool the planet if done on a large enough scale (Latham et al., 2008).To maximize the radiative flux response of MCB, previous studies have established that marine stratocumulus clouds off the west coasts of North America, South America, and southwest Africa are most susceptible to cloud brightening (Jones et al., 2009;Salter et al., 2008). Additionally, studies show that injecting Aitken mode particles with dry-diameters between 50 and 100 nm invoke greater aerosol-cloud indirect effects and require less injected mass to achieve a similar forcing as compared to larger, accumulation mode particles (Connolly et al., 2014;Partanen et al., 2012;Wood, 2021). Nonetheless, additional studies demonstrate that an injection of

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Distinct regional meteorological influences on low cloud albedo susceptibility over global marine stratocumulus regions

Zhang

Feingold

2022

Preprint

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Marine stratocumuli cool the Earth effectively due to their high reflectance of incoming solar radiation and persistent occurrence. The susceptibility of cloud albedo to droplet number concentration perturbations depends strongly on large-scale meteorological conditions. Studies focused on the meteorological dependence of cloud adjustments often overlook the covariability among meteorological factors and their geographical and temporal variability. We use 8 years of satellite observations sorted by day and geographical location to show the global distribution of marine low-cloud albedo susceptibility. We find an overall cloud brightening potential for most marine warm clouds, which is more pronounced over subtropical coastal regions. A weak cloud darkening potential in the annual mean is evident over the remote SE Pacific and SE Atlantic. We show that large-scale meteorological fields from the ERA5 reanalysis data, including lower-tropospheric stability, free-tropospheric relative humidity, sea surface temperature, and boundary layer depth, have distinct covariabilities over each of the eastern subtropical ocean basins where marine stratocumuli prevail. This leads to a markedly different annual cycle in albedo susceptibility over each basin. Moreover, we find that basin-specific regional relationships between key meteorological factors and albedo susceptibilities are absent in a global analysis. Our results stress the importance of considering the geographical distinctiveness of temporal meteorological covariability when scaling up the local-to-global response of cloud albedo to aerosol perturbations.

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Assessing the potential efficacy of marine cloud brightening for cooling Earth using a simple heuristic model

Cited by 50 publications

References 96 publications

Simulating Aerosol Lifecycle Impacts on the Subtropical Stratocumulus‐to‐Cumulus Transition Using Large‐Eddy Simulations

Simulating Aerosol Lifecycle Impacts on the Subtropical Stratocumulus‐to‐Cumulus Transition Using Large‐Eddy Simulations

The Shortwave Radiative Flux Response to an Injection of Sea Salt Aerosols in the Gulf of Mexico

Distinct regional meteorological influences on low cloud albedo susceptibility over global marine stratocumulus regions

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