Reply on RC1

Abstract

<strong class="journal-contentHeaderColor">Abstract.</strong> Mitigation of carbonaceous aerosol emissions is expected to provide climate and health co-benefits. The accurate representation of carbonaceous aerosols in climate models is critical for reducing uncertainties in their climate feedback. In this regard, emission fluxes and aerosol life cycle processes are the two primary sources of uncertainties. Here, we demonstrate that the incorporation of a dynamic ageing scheme and emission estimates that are updated for the local sources improves the representation of carbonaceous aerosols over the Indian monsoon region in a regional climate model, RegCM, compared with its default configuration. The respective mean black carbon (BC) and organic carbon (OC) surface concentrations in 2010 are estimated to be 4.25 and 10.35 <span class="inline-formula">µ</span>g m<span class="inline-formula">^−3</span> over the Indo-Gangetic Plain (IGP) in the augmented model. The BC column burden over the polluted IGP is found to be 2.47 mg m<span class="inline-formula">^−2</span>, 69.95 % higher than in the default model configuration and much closer to available observations. The anthropogenic aerosol optical depth (AOD) increases by more than 19 % over the IGP due to the model enhancement, also leading to a better agreement with observed AOD. The respective top-of-the-atmosphere, surface, and atmospheric anthropogenic aerosol short-wave radiative forcing are estimated at <span class="inline-formula">−0.3</span>, <span class="inline-formula">−9.3</span>, and 9.0 W m<span class="inline-formula">^−2</span> over the IGP and <span class="inline-formula">−0.89</span>, <span class="inline-formula">−5.33</span>, and 4.44 W m<span class="inline-formula">^−2</span> over Peninsular India (PI). Our results suggest that the combined effect of two modifications leads to maximum improvements in the model performance in regions where emissions play a dominant role.