Black carbon lofts wildfire smoke high into the stratosphere to form a persistent plume

Black carbon lofts wildfire smoke high into the stratosphere to form a persistent plume

In 2017, western Canadian wildfires injected smoke into the stratosphere that was detectable by satellites for more than 8 months. The smoke plume rose from 12 to 23 kilometers within 2 months owing to solar heating of black carbon, extending the lifetime and latitudinal spread. Comparisons of model...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2019-08, Vol.365 (6453), p.587-590
Hauptverfasser: Yu, Pengfei, Toon, Owen B., Bardeen, Charles G., Zhu, Yunqian, Rosenlof, Karen H., Portmann, Robert W., Thornberry, Troy D., Gao, Ru-Shan, Davis, Sean M., Wolf, Eric T., de Gouw, Joost, Peterson, David A., Fromm, Michael D., Robock, Alan
Format: Artikel
Sprache:eng
Schlagworte:
Atmospheric chemistry
Black carbon
Canada
Carbon
Computer simulation
Heat
Lofting
Organic carbon
Organic chemistry
Photochemical reactions
Photochemicals
Photochemistry
Satellite observation
Smoke
Solar heating
Stratosphere
Stratospheric Ozone - analysis
Wildfires
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Zusammenfassung:In 2017, western Canadian wildfires injected smoke into the stratosphere that was detectable by satellites for more than 8 months. The smoke plume rose from 12 to 23 kilometers within 2 months owing to solar heating of black carbon, extending the lifetime and latitudinal spread. Comparisons of model simulations to the rate of observed lofting indicate that 2% of the smoke mass was black carbon. The observed smoke lifetime in the stratosphere was 40% shorter than calculated with a standard model that does not consider photochemical loss of organic carbon. Photochemistry is represented by using an empirical ozone-organics reaction probability that matches the observed smoke decay. The observed rapid plume rise, latitudinal spread, and photochemical reactions provide new insights into potential global climate impacts from nuclear war.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.aax1748