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Exceptional stratospheric contribution to human fingerprints on atmospheric temperature.

Benjamin D SanterStephen Po-ChedleyLilong ZhaoCheng-Zhi ZouQiang FuSusan SolomonDavid W J ThompsonCarl MearsKarl E Taylor
Published in: Proceedings of the National Academy of Sciences of the United States of America (2023)
In 1967, scientists used a simple climate model to predict that human-caused increases in atmospheric CO 2 should warm Earth's troposphere and cool the stratosphere. This important signature of anthropogenic climate change has been documented in weather balloon and satellite temperature measurements extending from near-surface to the lower stratosphere. Stratospheric cooling has also been confirmed in the mid to upper stratosphere, a layer extending from roughly 25 to 50 km above the Earth's surface (S 25 - 50 ). To date, however, S 25 - 50 temperatures have not been used in pattern-based attribution studies of anthropogenic climate change. Here, we perform such a "fingerprint" study with satellite-derived patterns of temperature change that extend from the lower troposphere to the upper stratosphere. Including S 25 - 50 information increases signal-to-noise ratios by a factor of five, markedly enhancing fingerprint detectability. Key features of this global-scale human fingerprint include stratospheric cooling and tropospheric warming at all latitudes, with stratospheric cooling amplifying with height. In contrast, the dominant modes of internal variability in S 25 - 50 have smaller-scale temperature changes and lack uniform sign. These pronounced spatial differences between S 25 - 50 signal and noise patterns are accompanied by large cooling of S 25 - 50 (1 to 2[Formula: see text]C over 1986 to 2022) and low S 25 - 50 noise levels. Our results explain why extending "vertical fingerprinting" to the mid to upper stratosphere yields incontrovertible evidence of human effects on the thermal structure of Earth's atmosphere.
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