Smoke-weather interaction affects extreme wildfires in diverse coastal regions
Huang, X.; Ding, K.; Liu, J.; Wang, Z.; Tang, R.; Xue, L.; Wang, H.; Zhang, Q.; Tan, Z.-M.; Fu, C.; Davis, S.J.; Andreae, M.O.; Ding, A. (2023). Smoke-weather interaction affects extreme wildfires in diverse coastal regions. Science (Wash.) 379(6631): 457-461. https://dx.doi.org/10.1126/science.add9843
In: Science (Washington). American Association for the Advancement of Science: New York, N.Y. ISSN 0036-8075; e-ISSN 1095-9203, meer
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| Auteurs | | Top |
- Huang, X.
- Ding, K.
- Liu, J.
- Wang, Z.
- Tang, R.
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- Xue, L.
- Wang, H.
- Zhang, Q.
- Tan, Z.-M.
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- Fu, C.
- Davis, S.J.
- Andreae, M.O.
- Ding, A.
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| Abstract |
Extreme wildfires threaten human lives, air quality, and ecosystems. Meteorology plays a vital role in wildfire behaviors, and the links between wildfires and climate have been widely studied. However, it is not fully clear how fire-weather feedback affects short-term wildfire variability, which undermines our ability to mitigate fire disasters. Here, we show the primacy of synoptic-scale feedback in driving extreme fires in Mediterranean and monsoon climate regimes in the West Coast of the United States and Southeastern Asia. We found that radiative effects of smoke aerosols can modify near-surface wind, air dryness, and rainfall and thus worsen air pollution by enhancing fire emissions and weakening dispersion. The intricate interactions among wildfires, smoke, and weather form a positive feedback loop that substantially increases air pollution exposure. |
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