Atmospheric responses to the redistribution of anthropogenic aerosols

Wang, Yuan; Jiang, Jonathan H.; Su, Hui

doi:10.1002/2015jd023665

Cited by 88 publications

(59 citation statements)

References 48 publications

(64 reference statements)

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“…However, the aerosol perturbations at cloud-scale affect the regional and global circulation, and these regional-through global scale changes feed back as meteorological influences on cloud processes [112,133,150,151]. This means that constraining ERF aci requires understanding the microscale, the cloud process scale, and the global scale, as well as the interactions between scales.…”

Section: Why Are Erf Aci Estimates So Challenging?mentioning

confidence: 99%

The Radiative Forcing of Aerosol–Cloud Interactions in Liquid Clouds: Wrestling and Embracing Uncertainty

Mülmenstädt

Feingold

2018

Curr Clim Change Rep

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This article discusses some of the challenges that have limited progress in quantifying the radiative forcing associated with aerosol-cloud interactions (ACI) in warm (liquid-water) clouds. It reviews recent progress and suggests new ways of viewing the problem that might accelerate progress. It calls for much greater attention to the scale problem, both in terms of aerosol-cloud process representation in models and comparison with observations. It suggests careful consideration of the balance in detail with which processes are represented, and proposes a merging of detailed process understanding and system-wide behavior. In this spirit, it advocates tackling the problem with models of varying complexity that consider both the depth and breadth of the complex dynamical system. Finally, it considers shifting attention from untangling aerosol and meteorological effects on cloud systems towards understanding the co-variability of key aerosol and meteorological drivers of cloud systems.

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Section: Why Are Erf Aci Estimates So Challenging?mentioning

confidence: 99%

The Radiative Forcing of Aerosol–Cloud Interactions in Liquid Clouds: Wrestling and Embracing Uncertainty

Mülmenstädt

Feingold

2018

Curr Clim Change Rep

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“…Besides the local aerosol sources, the atmospheric transport of aerosol pollutants from the Asian continent (e.g., Jiang et al, 2007;Wang et al, 2015;Hu et al, 2016) is also a significant contributor to aerosol loading throughout the Pacific basin. Asian aerosols can reach relatively high concentrations above the marine boundary layer in the western US, representing as much as 85 % of the total atmospheric burden of PM at some sites (VanCuren, 2003).…”

mentioning

confidence: 99%

Impacts of aerosols on seasonal precipitation and snowpack in California based on convection-permitting WRF-Chem simulations

Gu²,

Jiang

et al. 2018

Atmos. Chem. Phys.

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Abstract. A version of the WRF-Chem model with fully coupled aerosol-meteorology-snowpack is employed to investigate the impacts of various aerosol sources on precipitation and snowpack in California. In particular, the impacts of locally emitted anthropogenic and dust aerosols, and aerosols transported from outside California are studied. We differentiate three pathways of aerosol effects: aerosol-radiation interaction (ARI), aerosol-snow interaction (ASI), and aerosol-cloud interaction (ACI). The convection-permitting model simulations show that precipitation, snow water equivalent (SWE), and surface air temperature averaged over the whole domain (34-42 • N, 117-124 • W, not including ocean points) are reduced when aerosols are included, therefore reducing large biases in these variables due to the absence of aerosol effects in the model. Aerosols affect California water resources through the warming of mountaintops and the reduction of precipitation; however, different aerosol sources play different roles in changing surface temperature, precipitation, and snowpack in California by means of various weights of the three pathways. ARI by all aerosols mainly cools the surface, leading to slightly increased SWE over the mountains. Locally emitted dust aerosols warm the surface of mountaintops through ASI, in which the reduced snow albedo associated with dusty snow leads to more surface absorption of solar radiation and reduced SWE. Transported aerosols and local anthropogenic aerosols play a dominant role in increasing nonprecipitating clouds but reducing precipitation through ACI, leading to reduced SWE and runoff on the Sierra Nevada, as well as the warming of mountaintops associated with decreased SWE and hence lower surface albedo. The average changes in surface temperature from October 2012 to June 2013 are about −0.19 and 0.22 K for the whole domain and over mountaintops, respectively. Overall, the averaged reduction during October to June is about 7 % for precipitation, 3 % for SWE, and 7 % for surface runoff for the whole domain, while the corresponding numbers are 12, 10, and 10 % for the mountaintops. The reduction in SWE is more significant in a dry year, with 9 % for the whole domain and 16 % for the mountaintops. The maximum reduction of ∼ 20 % in precipitation occurs in May and is associated with the maximum aerosol loading, leading to the largest decrease in SWE and surface runoff over that period. It is also found that dust aerosols can cause early snowmelt on the mountaintops and reduced surface runoff after April.

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“…A recent study by Y. Wang et al . [] indicated that the spatial redistribution of aerosols might have significant implications for large‐scale circulation. In addition, the seasonal variation of vertical cloud structures is different which may induce different aerosol‐cloud microphysics interactions [ Wang et al ., ].…”

Section: Introductionmentioning

confidence: 85%

“…Many modeling and observational studies have been conducted to investigate aerosol‐cloud‐radiation‐precipitation interactions [ Ackerman et al ., ; Guo et al ., ; Rosenfeld , ; Tao et al ., ; Twomey , ; H. Wang et al ., ; Y. Wang et al ., ]. Most aerosol‐cloud interaction studies that involve warm clouds find consistent responses in cloud properties: more aerosols result in more, but smaller, cloud droplets and thus enhanced cloud albedo if the total water keeps constant.…”

Section: Introductionmentioning

confidence: 99%

Aerosol effects on summer monsoon over Asia during 1980s and 1990s

et al. 2016

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The Community Earth System Model is used to study the aerosol climate effects during the 1980s and 1990s in which the anthropogenic SO2 emissions decreased in North America and Western Europe and increased in East and South Asia. From the 100 year simulations, aerosol forcing results in cooler (−0.13 K) and drier (−0.01 mm/day) atmosphere with less shortwave radiation flux at the surface (−0.37 W/m2). The clear‐sky shortwave radiation flux decreased over East Asia (−0.81 W/m2) and South Asia (−1.09 W/m2), but increased over Western Europe (+1.16 W/m2) and North America (+0.39 W/m2), consistent with aerosol loading changes. While changes in spatial distributions of all‐sky shortwave radiation and surface temperature are closely related to cloud changes, the changes in wind and precipitation do not correspond to aerosol loading changes, indicating the complexity of aerosol‐cloud circulation interactions. The East and South Asia monsoons were generally weakened due mainly to southward shift of the 200 hPa East Asia Jet (EAJ) and decrease in 850 hPa winds; annual precipitation decreased by 2% in South Asia but increased by 2% in Yangtze‐Huai River Valley over East Asia. The uncertainties associated with aerosol climate effects are addressed within the context of model variability and the global warming effect. For the latter, while the aerosol effects decrease the greenhouse warming on the global mean, the regional responses are different. Nevertheless, the characteristics of aerosol climate effects, including the southward 200 hPa EAJ and weakened South Asia monsoon, still persist when the climate becomes warmer, although the strength and the geographical distribution are slightly modulated.

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Atmospheric responses to the redistribution of anthropogenic aerosols

Cited by 88 publications

References 48 publications

The Radiative Forcing of Aerosol–Cloud Interactions in Liquid Clouds: Wrestling and Embracing Uncertainty

The Radiative Forcing of Aerosol–Cloud Interactions in Liquid Clouds: Wrestling and Embracing Uncertainty

Impacts of aerosols on seasonal precipitation and snowpack in California based on convection-permitting WRF-Chem simulations

Aerosol effects on summer monsoon over Asia during 1980s and 1990s

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