par Whitburn, Simon 
;Clarisse, Lieven ;Bouillon, Marie M.;Safieddine, Sarah;George, Martin Andreas Robert M.;Dewitte, Steven;De Longueville, Hélène ;Coheur, Pierre ;Clerbaux, Cathy
Référence npj Climate and Atmospheric Science, 4, 1, 48
Publication Publié, 2021-12
;Clarisse, Lieven ;Bouillon, Marie M.;Safieddine, Sarah;George, Martin Andreas Robert M.;Dewitte, Steven;De Longueville, Hélène ;Coheur, Pierre ;Clerbaux, Cathy Référence npj Climate and Atmospheric Science, 4, 1, 48
Publication Publié, 2021-12
Article révisé par les pairs
| Résumé : | In recent years, the interest has grown in satellite-derived hyperspectral radiance measurements for assessing the individual impact of climate drivers and their cascade of feedbacks on the outgoing longwave radiation (OLR). In this paper, we use 10 years (2008–2017) of reprocessed radiances from the infrared atmospheric sounding interferometer (IASI) to evaluate the linear trends in clear-sky spectrally resolved OLR (SOLR) in the range [645–2300] cm−1. Spatial inhomogeneities are observed in most of the analyzed spectral regions. These mostly reflected the natural variability of the atmospheric temperature and composition but long-term changes in greenhouse gases concentrations are also highlighted. In particular, the increase of atmospheric CO2 and CH4 led to significant negative trends in the SOLR of −0.05 to −0.3% per year in the spectral region corresponding to the ν2 and the ν3 CO2 and in the ν4 CH4 band. Most of the trends associated with the natural variability of the OLR can be related to the El Niño/Southern Oscillation activity and its teleconnections in the studied period. This is the case for the channels most affected by the temperature variations of the surface and the first layers of the atmosphere but also for the channels corresponding to the ν2 H2O and the ν3 O3 bands. |
