Abstract
Abstract. Observations and model calculations indicate that highly non-linear multiphase atmospheric processes involving inorganic Cl and Br significantly impact tropospheric chemistry and composition, aerosol evolution, and radiative transfer. The sensitivity of global atmospheric chemistry to the production of marine aerosol and the associated activation and cycling of inorganic Cl and Br was investigated using a size-resolved multiphase coupled chemistry–global climate model (National Center for Atmospheric Research's Community Atmosphere Model (CAM) v3.6.33). Simulated results revealed strong meridional and vertical gradients in Cl and Br species. They also point to possible physicochemical mechanisms that may account for several previously unexplained phenomena, including the enrichment of Br- in submicron aerosol and the presence of a BrO maximum in the polar free troposphere. However, simulated total volatile inorganic Br mixing ratios in the troposphere were generally higher than observed, due in part to the overly efficient net production of BrCl. In addition, the emission scheme for marine aerosol and associated Br−, which is the only source for Br in the model, overestimates emission fluxes from the high-latitude Southern Ocean. Br in the stratosphere was lower than observed due to the lack of long-lived precursor organobromine species in the simulation. Comparing simulations using chemical mechanisms with and without reactive Cl and Br species demonstrates a significant temporal and spatial sensitivity of primary atmospheric oxidants (O3, HOx, NOx), CH4, non-methane hydrocarbons (NMHCs), and dimethyl sulfide (DMS) to halogen cycling. Globally, halogen chemistry had relatively less impact on SO2 and non-sea-salt (nss) SO42− although significant regional differences were evident. Although variable geographically, much of this sensitivity is attributable to either over-vigorous activation of Br (primarily BrCl) via the chemical mechanism or overproduction of sea-salt aerosol simulated under higher-wind regimes. In regions where simulated mixing ratios of reactive Br and Cl fell within observed ranges, though, halogen chemistry drove large changes in oxidant fields and associated chemical processes relative to simulations with no halogens. However, the overall simulated impacts of Br chemistry globally are overestimated and thus caution is warranted in their interpretation.
Highlights
The development of comprehensive global Earth system models that are able to accurately simulate the climate system requires detailed understanding and treatment of multiphase atmospheric processes relevant to aerosol evolution and radiative transfer
Each mode consists of internally mixed populations of non-sea-salt SO24−, organic matter from primary sources (OM), secondary organic aerosol (SOA) from volatile organic precursors, black carbon (BC), inorganic sea salt, and mineral dust
Direct surface emissions of dimethyl sulfide (DMS), SO2, SOA precursor gases, subgrid-scale NH4HSO4, NH3, and NOx were based on Dentener et al (2006)
Summary
The development of comprehensive global Earth system models that are able to accurately simulate the climate system requires detailed understanding and treatment of multiphase atmospheric processes relevant to aerosol evolution and radiative transfer. For this analysis, a comprehensive multiphase atmospheric chemistry mechanism was fully coupled with a microphysically enabled aerosol-size-resolving general circulation model. We used a 3-mode size-resolving aerosol module (Modal Aerosol Module) version of the three-dimensional (3-D) National Center for Atmospheric Research’s Community Atmosphere Model (CAM version 3.6.33; Gent et al, 2009; Liu et al, 2012; hereafter referred to as modal-CAM) coupled to the multiphase chemical module MECCA (Module Efficiently Calculating the Chemistry of the Atmosphere; Sander et al, 2005) This comprehensive chemical scheme explicitly evaluates the multiphase production and processing of inorganic Br and Cl. MECCA was implemented with minimal parameterization and tuning, permitting quantitative evaluation of limitations in the chemical mechanism. The companion paper by Long et al (2013) describes the coupled modeling system and chemical mechanism in detail
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