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Characterization of speciated aerosol direct radiative forcing over California
Author(s) -
Zhao Chun,
Ruby Leung L.,
Easter Richard,
Hand Jenny,
Avise Jeremy
Publication year - 2013
Publication title -
journal of geophysical research: atmospheres
Language(s) - English
Resource type - Journals
eISSN - 2169-8996
pISSN - 2169-897X
DOI - 10.1029/2012jd018364
Subject(s) - aerosol , radiative forcing , atmospheric sciences , environmental science , weather research and forecasting model , radiative transfer , sulfate aerosol , atmosphere (unit) , sulfate , climatology , forcing (mathematics) , meteorology , chemistry , physics , geology , organic chemistry , quantum mechanics
The WRF‐Chem model, with the added capability of diagnosing the direct radiative forcing of individual aerosol species, is used to characterize the spatial and seasonal distribution of speciated aerosol direct radiative forcing over California. Overall, the simulation in 2005 is able to reproduce the observed spatial and seasonal distribution of total PM 2.5 mass concentration and the relative contribution from individual aerosol species. On statewide average over California, all aerosol species reduce the surface net radiation fluxes, with a total by about 1.5 W m −2 (winter minimum) to 3 W m −2 (summer maximum). Elemental carbon (EC) is the largest contributor in summer (−1.1 W m −2 and ~35%), and sulfate is the largest in winter (−0.45 W m −2 and ~30%). In the atmosphere, total aerosol introduces a warming effect of about 0.5 W m −2 (winter minimum) to 2 W m −2 (summer maximum). EC and dust contribute about 75 − 95% and 1 − 10% of the total warming through the seasons, respectively. At the top of the atmosphere (TOA), the overall total aerosol direct radiative effect is cooling of −1.0 W m −2 through the seasons, with sulfate as the biggest contributor of −0.4 W m −2 (winter minimum) to −0.7 W m −2 (summer maximum). EC produces a TOA warming of up to about 0.7 W m −2 , whereas all other aerosol species produce a TOA cooling. The diagnostic method implemented in WRF‐Chem can be applied to other regions to understand the roles of different aerosols in the direct radiative forcing and regional climate.