Litcius/Paper detail

Regional Response of Land Hydrology and Carbon Uptake to Different Amounts of Solar Radiation Modification

Mengying Zhao, Long Cao

2022Earth s Future18 citationsDOIOpen Access PDF

Abstract

Abstract Solar radiation modification (SRM) is a proposed method to cool the Earth by intentionally perturbing the Earth's energy balance. One concern about the effect of SRM is disparities in the regional climate response. In this study, we use the Community Earth System Model (CESM1.2) to analyze the regional response of land hydrology and terrestrial carbon uptake to different amounts of SRM. The SRM is implemented by a uniform increase in volcanic‐size sulfate aerosols in the stratosphere under a doubling of atmospheric CO 2 . Our results show that different amounts of SRM could either moderate or exacerbate CO 2 ‐induced changes in land hydrology including precipitation, precipitation minus evapotranspiration, and soil moisture (SM), but the effect varies widely across regions and specific variables. An “optimal” amount of SRM that moderates land hydrology changes for one region might exacerbate changes for other regions (or vice versa). Also, our study shows that for quite a few regions, partial SRM moderates CO 2 ‐induced change in precipitation minus evaporation but exacerbates changes in CO 2 ‐induced SM. The response of terrestrial Net primary productivity (NPP) to different amounts of SRM shows large regional disparities, depending on whether temperature or water availability constrains NPP more. Our study also shows that the effect of CO 2 physiological forcing plays a key role in regulating land hydrology response to SRM, especially at the regional scale.

Topics & Concepts

Environmental scienceEvapotranspirationPrecipitationRadiative forcingHydrology (agriculture)Primary productionAtmospheric sciencesClimate changeClimatologyEcosystemMeteorologyEcologyGeologyGeotechnical engineeringPhysicsBiologyClimate Change and GeoengineeringAtmospheric Ozone and ClimateAtmospheric and Environmental Gas Dynamics