Earth's Sea Ice Radiative Effect From 1980 to 2023

Sea ice cools Earth by reducing its absorbed solar energy. We combine radiative transfer modeling with satellite-derived surface albedo, sea ice, and cloud distributions to quantify the top-of-atmosphere sea ice radiative effect (SIRE). Averaged over 1980–2023, Arctic and Antarctic SIREs range from...

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Bibliographic Details
Main Authors: Duspayev, A., Flanner, M. G., Riihelä, A.
Other Authors: Ilmatieteen laitos, Finnish Meteorological Institute, orcid:0000-0001-6581-8792
Format: Article in Journal/Newspaper
Language:English
Published: John Wiley & Sons 2024
Subjects:
ice
sea ice
seas
climate changes
polar regions
arctic region
glaciology
oceanography
climate
glaciers
jää
merijää
meret
ilmastonmuutokset
napa-alueet
arktinen alue
glasiologia
meritiede
ilmasto
jäätiköt
Antarctic
Arctic
albedo
Antarc*
Arktinen alue
Sea ice
Online Access:http://hdl.handle.net/10138/585291
Description
Summary:Sea ice cools Earth by reducing its absorbed solar energy. We combine radiative transfer modeling with satellite-derived surface albedo, sea ice, and cloud distributions to quantify the top-of-atmosphere sea ice radiative effect (SIRE). Averaged over 1980–2023, Arctic and Antarctic SIREs range from −0.64 to −0.86 W m−2 and −0.85 to −0.98 W m−2, respectively, with different cloud data sets and assumptions of climatological versus annually-varying clouds. SIRE trends, however, are relatively insensitive to these assumptions. Arctic SIRE has weakened quasi-linearly at a rate of 0.04–0.05 W m−2 decade−1, implying a 21%–27% reduction in the reflective power of Arctic sea ice since 1980. Antarctic sea ice exhibited a regime change in 2016, resulting in 2016–2023 Antarctic and global SIRE being 0.08–0.12 and 0.22–0.27 W m−2 weaker, respectively, relative to 1980–1988. Global sea ice has therefore lost 13%–15% of its planetary cooling effect since the early/mid 1980s, and the implied global sea ice albedo feedback is 0.24–0.38 W m−2 K−1.

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