Distinguishing the impacts of natural and anthropogenic aerosols on global gross primary productivity through diffuse fertilization effect

Abstract

Aerosols can enhance ecosystem productivity by increasing diffuse radiation. Such diffuse fertilization effects (DFEs) vary among different aerosol compositions and sky conditions. Here, we apply a suite of chemical, radiation, and vegetation models in combination with ground- and satellite-based measurements to assess the impacts of natural and anthropogenic aerosol species on gross primary productivity (GPP) through DFE from 2001-2014. Globally, aerosols enhance GPP by 8.9gPggCgyr-1 under clear-sky conditions but only 0.95gPggCgyr-1 under all-sky conditions. Anthropogenic aerosols account for 41g% of the total GPP enhancement, though they contribute only 25g% to the increment of diffuse radiation. Sulfate/nitrate aerosols from anthropogenic sources make dominant contributions of 33g% (36g%) to aerosol DFE under all-sky (clear-sky) conditions, followed by the fraction of 18g% (22g%) by organic carbon aerosols from natural sources. In contrast to other species, black carbon aerosols reduce global GPP by 0.28 (0.12)gPggCgyr-1 under all-sky (clear-sky) conditions. Long-term simulations show that aerosol DFE increases 2.9g%gyr-1 under all-sky conditions mainly because of a downward trend in cloud amount. This study suggests that the impacts of aerosols and cloud should be considered in projecting future changes of ecosystem productivity under varied emission scenarios.