Intercomparison and improvement of two-stream shortwave radiative transfer schemes in Earth system models for a unified treatment of cryospheric surfaces
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Published:2019-09-06
Issue:9
Volume:13
Page:2325-2343
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ISSN:1994-0424
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Container-title:The Cryosphere
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language:en
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Short-container-title:The Cryosphere
Author:
Dang ChengORCID, Zender Charles S.ORCID, Flanner Mark G.
Abstract
Abstract. Snow is an important climate regulator because it greatly
increases the surface albedo of middle and high latitudes of the Earth.
Earth system models (ESMs) often adopt two-stream approximations with
different radiative transfer techniques, the same snow therefore has
different solar radiative properties depending whether it is on land or on
sea ice. Here we intercompare three two-stream algorithms widely used in
snow models, improve their predictions at large zenith angles, and introduce
a hybrid model suitable for all cryospheric surfaces in ESMs. The algorithms
are those employed by the SNow ICe and Aerosol Radiative (SNICAR) module
used in land models, dEdd–AD used in Icepack, the column physics used
in the Los Alamos sea ice model CICE and MPAS-Seaice, and a two-stream
discrete-ordinate (2SD) model. Compared with a 16-stream benchmark model,
the errors in snow visible albedo for a direct-incident beam from all three
two-stream models are small (<±0.005) and increase as snow
shallows, especially for aged snow. The errors in direct near-infrared
(near-IR) albedo are small (<±0.005) for solar zenith angles
θ<75∘, and increase as θ increases. For
diffuse incidence under cloudy skies, dEdd–AD produces the most accurate
snow albedo for both visible and near-IR (<±0.0002) with the
lowest underestimate (−0.01) for melting thin snow. SNICAR performs
similarly to dEdd–AD for visible albedos, with a slightly larger
underestimate (−0.02), while it overestimates the near-IR albedo by an order
of magnitude more (up to 0.04). 2SD overestimates both visible and near-IR
albedo by up to 0.03. We develop a new parameterization that adjusts the
underestimated direct near-IR albedo and overestimated direct near-IR
heating persistent across all two-stream models for θ>75∘. These results are incorporated in a hybrid model SNICAR-AD,
which can now serve as a unified solar radiative transfer model for snow in
ESM land, land ice, and sea ice components.
Funder
U.S. Department of Energy
Publisher
Copernicus GmbH
Subject
Earth-Surface Processes,Water Science and Technology
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