Journal of Advances in Modeling Earth Systems (Feb 2018)

Impact of Precipitating Ice Hydrometeors on Longwave Radiative Effect Estimated by a Global Cloud‐System Resolving Model

  • Ying‐Wen Chen,
  • Tatsuya Seiki,
  • Chihiro Kodama,
  • Masaki Satoh,
  • Akira T. Noda

DOI
https://doi.org/10.1002/2017MS001180
Journal volume & issue
Vol. 10, no. 2
pp. 284 – 296

Abstract

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Abstract Satellite observation and general circulation model (GCM) studies suggest that precipitating ice makes nonnegligible contributions to the radiation balance of the Earth. However, in most GCMs, precipitating ice is diagnosed and its radiative effects are not taken into account. Here we examine the longwave radiative impact of precipitating ice using a global nonhydrostatic atmospheric model with a double‐moment cloud microphysics scheme. An off‐line radiation model is employed to determine cloud radiative effects according to the amount and altitude of each type of ice hydrometeor. Results show that the snow radiative effect reaches 2 W m−2 in the tropics, which is about half the value estimated by previous studies. This effect is strongly dependent on the vertical separation of ice categories and is partially generated by differences in terminal velocities, which are not represented in GCMs with diagnostic precipitating ice. Results from sensitivity experiments that artificially change the categories and altitudes of precipitating ice show that the simulated longwave heating profile and longwave radiation field are sensitive to the treatment of precipitating ice in models. This study emphasizes the importance of incorporating appropriate treatments for the radiative effects of precipitating ice in cloud and radiation schemes in GCMs in order to capture the cloud radiative effects of upper level clouds.

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