Comparing multi-model ensemble simulations with observations and decadal projections of upper atmospheric variations following the Hunga eruption
Zhuo, Z., Wang, X., Zhu, Y., Yu, W., Bednarz, E. M., et al. (2025). Comparing multi-model ensemble simulations with observations and decadal projections of upper atmospheric variations following the Hunga eruption. Atmospheric Chemistry and Physics, doi:https://doi.org/10.5194/acp-25-13161-2025
| Title | Comparing multi-model ensemble simulations with observations and decadal projections of upper atmospheric variations following the Hunga eruption |
|---|---|
| Genre | Article |
| Author(s) | Z. Zhuo, Xinyue Wang, Y. Zhu, W. Yu, E. M. Bednarz, E. Fleming, P. R. Colarco, S. Watanabe, D. Plummer, G. Stenchikov, William Randel, A. Bourassa, V. Aquila, T. Sekiya, M. R. Schoeberl, Simone Tilmes, Jun Zhang, P. J. Kushner, F. S. R. Pausata |
| Abstract | The Hunga Tonga-Hunga Ha'apai Model-Observation Comparison (HTHH-MOC) project aims to comprehensively investigate the evolution of volcanic water vapor and sulfur emissions and their subsequent atmospheric impacts and underlying response mechanisms using state-of-the-art global climate models. This study evaluates multi-model ensemble simulations participating in the HTHH-MOC free-run experiment with climate projections for 10 years (2022-2032). Model results are evaluated against satellite observations to assess their ability to reproduce the observed evolution of stratospheric water vapor, aerosols, temperature, and ozone from 2022 to 2024. The participating models accurately capture the observed distribution patterns and associated upper atmospheric responses, providing confidence for their future projections. Model simulations suggest that the Hunga eruption-induced stratospheric water vapor anomaly lasts 4-7 years, with a water vapor e-folding time of 31-43 months. This prolonged water vapor perturbation leads to significant stratospheric and mesospheric cooling, resulting in significant ozone loss in the upper stratosphere and lower mesosphere for 7-10 years. Comparisons between simulations with both SO2 and H2O emissions and those with H2O-only emissions indicate that the pronounced dipole response with upper-stratospheric cooling and lower-stratospheric warming is driven by the combined effects of SO2 and H2O injections. These results highlight the prolonged atmospheric impacts of the Hunga eruption and the potential critical role of stratospheric water vapor in modulating long-term atmospheric chemistry and dynamics. |
| Publication Title | Atmospheric Chemistry and Physics |
| Publication Date | Oct 21, 2025 |
| Publisher's Version of Record | https://doi.org/10.5194/acp-25-13161-2025 |
| OpenSky Citable URL | https://n2t.net/ark:/85065/d7571hgz |
| OpenSky Listing | View on OpenSky |
| ACOM Affiliations | ACOMVISITORS, ACRESP, MODELING |