气候模式中的黑碳间接辐射效应

Tellus B: Chemical and Physical Meteorology Pub Date : 2017-01-01 DOI:10.1080/16000889.2017.1369342

R. Cherian, J. Quaas, M. Salzmann, L. Tomassini

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引用次数: 23

摘要

利用大气-海洋环流耦合模式MPI-ESM中的气溶胶模块，研究了由黑碳(BC)气溶胶引起的气溶胶-云相互作用以及隐含的气候响应。模拟显示，在BC排放源区域，特别是热带和中纬度地区，云滴数浓度(CDNC)提高了10-15%。较高的CDNC和从云水到雨水的自动转换减少解释了模式中热带地区(30S-30N)云水路径的增加。在全球平均水平上，云水和降水的变化可以忽略不计。由于气溶胶-云相互作用导致的BC的全球平均有效辐射强迫估计为，这可归因于模式中CDNC负担和(区域)云水的增加。全球平均温度和降雨响应分别为和，区域变化显著较大，主要发生在BC源的顺风区域。

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Black carbon indirect radiative effects in a climate model

Abstract The aerosol–cloud interactions due to black carbon (BC) aerosols, as well as the implied climate responses, are examined using an aerosol module in the coupled atmosphere–ocean general circulation model MPI-ESM. BC is simulated to enhance cloud droplet number concentration (CDNC) by 10–15% in the BC emission source regions, especially in the Tropics and mid-latitudes. Higher CDNC and reduced auto-conversion from cloud water to rain water explains the increased cloud water path over the tropical regions (30S–30N) in the model. In the global mean, the cloud water– as well as precipitation changes are negligibly small. The global-mean effective radiative forcing due to aerosol–cloud interactions for BC is estimated at , which is attributable to the increase in CDNC burden and (regionally) cloud water in the model. Global mean temperature and rainfall response were found to be and , respectively, with significantly larger regional changes mainly in the downwind regions from BC sources.

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Tellus B: Chemical and Physical Meteorology

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