Abstract
<strong class="journal-contentHeaderColor">Abstract.</strong> Black carbon (BC) is one of the dominant absorbing aerosol species in the atmosphere. It normally has complex fractal-like structures due to the aggregation process during combustion. A wide range of aerosolâradiation interactions (ARIs) of BC have been reported throughout experimental and modeling studies. One reason for the large discrepancies among multiple studies is the application of the oversimplified spherical morphology for BC in ARI estimates. In current climate models, the Mie theory is commonly used to calculate the optical properties of spherical BC aerosols. Here, we employ a regional chemical transport model coupled with a radiative transfer code that utilizes the non-spherical BC optical simulations to re-evaluate the effects of particles' morphologies on BC shortwave ARI, and the wavelength range of 0.3â4.0â<span class="inline-formula">µ</span>m was considered. Anthropogenic activities and wildfires are two major sources of BC emissions. Therefore, we choose the typical polluted area in eastern China, which is dominated by anthropogenic emissions, and the fire region in the northwest US, which is dominated by fire emissions in this study. A 1-month simulation in eastern China and a 7âd simulation in the fire region in the northwest US were performed. The fractal BC model generally presents a larger clear-sky ARI compared to the spherical BC model. Assuming BC particles are externally mixed with other aerosols, the relative differences in the time-averaged clear-sky ARI between the fractal model with a fractal dimension (<span class="inline-formula"><i>D</i><sub>f</sub></span>) of 1.8 and the spherical model are 12.1â%â20.6â% and 10.5â%â14.9â% for typical polluted urban cities in China and fire sites in the northwest US, respectively. Furthermore, the regional-mean clear-sky ARI is also significantly affected by the BC morphology, and relative differences of 17.1â% and 38.7â% between the fractal model with a <span class="inline-formula"><i>D</i><sub>f</sub></span> of 1.8 and the spherical model were observed in eastern China and the northwest US, respectively. However, the existence of clouds would weaken the BC morphological effects. The time-averaged all-sky ARI relative differences between the fractal model with a <span class="inline-formula"><i>D</i><sub>f</sub></span> of 1.8 and the spherical model are 4.9â%â6.4â% and 9.0â%â11.3â% in typical urban polluted cities and typical fire sites, respectively. Besides, for the regional-mean all-sky ARI, the relative differences between the fractal model and the spherical model are less than 7.3â% and 16.8â% in the polluted urban area in China and the fire region in the US, respectively. The results imply that current climate modeling may significantly underestimate the BC ARI uncertainties as the morphological effects on BC ARI are ignored in most climate models.
Highlights
Black carbon (BC), as the main absorbing aerosol in the atmosphere, exerts a positive radiative forcing, and lofts smoke plumes (Buseck and Buseck, 2000; Streets et al, 2006; Moosmüller et al, 2009)
Among all the radiative parameters, we investigated aerosol optical depth (AOD), aerosol absorption optical depth (AAOD), extinction Ångström exponent (EAE), absorption Ångström exponent (AAE), single-scattering albedo (SSA), and aerosol-radiation interactions (ARI) at the TOA, which were widely used in remote sensing and climate effect evaluation
The left column represents the typical cities in China, and the right column represents the sites in North America
Summary
Black carbon (BC), as the main absorbing aerosol in the atmosphere, exerts a positive radiative forcing, and lofts smoke plumes (Buseck and Buseck, 2000; Streets et al, 2006; Moosmüller et al, 2009). Extremely limited number of studies have evaluated the ARI of non-spherical BC in regional or global climate models. Expanding the modeling range to regions with 40 different emission characteristics is important to understand the effects of BC sources on aerosol-radiation interactions (ARI). Among all the radiative parameters, we investigated aerosol optical depth (AOD), aerosol absorption optical depth (AAOD), extinction Ångström exponent (EAE), absorption Ångström exponent (AAE), single-scattering albedo (SSA), and ARI at the TOA, which were widely used in remote sensing and climate effect evaluation. Note here EDGAR-HTAP anthropogenic inventory and FINN were provided for the MOZART 80 chemical mechanism, so we manually mapped the emission for the MOZART chemical mechanism to the CBM-Z chemical mechanism based on the study of Emmons et al (2010). The chemical initial and boundary conditions were obtained from the Model for Ozone and Related Tracer, version 4 (MOZART-4)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
