Hunga Tonga–Hunga Ha'apai Volcano Impact Model Observation Comparison (HTHH-MOC) project: experiment protocol and model descriptions

Yunqian Zhu; Hideharu Akiyoshi; Valentina Aquila; Elizabeth Asher; Ewa M. Bednarz; Slimane Bekki; Christoph Brühl; Amy H. Butler; Parker Case; Simon Chabrillat; Gabriel Chiodo; Margot Clyne; Peter R. Colarco; Sandip Dhomse; Lola Falletti; Eric Fleming; Ben Johnson; Andrin Jörimann; Mahesh Kovilakam; Gerbrand Koren; Ales Kuchar; Nicolas Lebas; Qing Liang; Cheng Cheng Liu; Graham Mann; Michael Manyin; Marion Marchand; Olaf Morgenstern; Paul Newman; Luke D. Oman; Freja F. Østerstrøm; Yifeng Peng; David Plummer; Ilaria Quaglia; William Randel; Samuel Rémy; Takashi Sekiya; Stephen Steenrod; Timofei Sukhodolov; Simone Tilmes; Kostas Tsigaridis; Rei Ueyama; Daniele Visioni; Xinyue Wang; Shingo Watanabe; Yousuke Yamashita; Pengfei Yu; Wandi Yu; Jun Zhang; Zhihong Zhuo

doi:10.5194/gmd-18-5487-2025

Hunga Tonga–Hunga Ha'apai Volcano Impact Model Observation Comparison (HTHH-MOC) project: experiment protocol and model descriptions

Yunqian Zhu
, Hideharu Akiyoshi
, Valentina Aquila
, Elizabeth Asher
, Ewa M. Bednarz
, Slimane Bekki
, Christoph Brühl
, Amy H. Butler
, Parker Case
, Simon Chabrillat
, Gabriel Chiodo
, Margot Clyne
, Peter R. Colarco
, Sandip Dhomse
, Lola Falletti
, Eric Fleming
, Ben Johnson
, Andrin Jörimann
, Mahesh Kovilakam
, Gerbrand Koren

Ales Kuchar, Nicolas Lebas, Qing Liang, Cheng Cheng Liu, Graham Mann, Michael Manyin, Marion Marchand, Olaf Morgenstern, Paul Newman, Luke D. Oman, Freja F. Østerstrøm, Yifeng Peng, David Plummer, Ilaria Quaglia, William Randel, Samuel Rémy, Takashi Sekiya, Stephen Steenrod, Timofei Sukhodolov, Simone Tilmes, Kostas Tsigaridis, Rei Ueyama, Daniele Visioni, Xinyue Wang, Shingo Watanabe, Yousuke Yamashita, Pengfei Yu, Wandi Yu, Jun Zhang, Zhihong Zhuo

University of Colorado Boulder
National Oceanic and Atmospheric Administration
National Institute for Environmental Studies of Japan
American University Washington DC
Sorbonne Université
Max Planck Institute for Chemistry
NASA Goddard Space Flight Center
Royal Belgian Institute for Space Aeronomy
Swiss Federal Institute of Technology Zurich
CSIC
University of Maryland, College Park
University of Leeds
Science Systems and Applications, Inc.
Met Office
Physikalisch-Meteorologisches Observatorium Davos World Radiation Center
NASA Langley Research Center
Utrecht University
University of Natural Resources and Life Sciences, Vienna
NIWA
University of Canterbury
Harvard University
University of Copenhagen
Lanzhou University
Climate Research Branch
National Center for Atmospheric Research
HYGEOS
Japan Agency for Marine-Earth Science and Technology
Columbia University
NASA Goddard Institute for Space Studies
NASA Ames Research Center
Cornell University
Tohoku University
Jinan University
Lawrence Livermore National Laboratory
Université du Québec à Montréal

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

The 2022 Hunga volcanic eruption injected a significant amount of water vapor and a moderate amount of sulfur dioxide into the stratosphere, causing observable responses in the climate system. We have developed a model–observation comparison project to investigate the evolution of volcanic water and aerosols and their impacts on atmospheric dynamics, chemistry, and climate, using several state-of-the-art chemistry climate models. The project goals are (1) to evaluate the current chemistry–climate models to quantify their performance in comparison to observations and (2) to understand atmospheric responses in the Earth system after this exceptional event and investigate the potential impacts in the projected future. To achieve these goals, we designed specific experiments for direct comparisons to observations, for example from balloons and the Microwave Limb Sounder satellite instrument. Experiment 1 consists of two sets of free-running ensemble experiments from 2022 to 2031: one with fixed sea-surface temperatures and sea ice and one with coupled ocean. These experiments will help to understand the long-term evolution of water vapor and aerosols; quantify HTHH effects on stratospheric and mesospheric temperatures, dynamics, and transport; understand the impact of dynamic changes on ozone chemistry; quantify the net radiative forcings; and evaluate any surface climate impact. Experiment 2 is a nudged-run experiment from 2022 to 2023 using observed meteorology. To allow participation of more climate models with varying complexities of aerosol simulation, we include two sets of simulations in Experiment 2: Experiment 2a is designed for models with internally generated aerosol, while Experiment 2b is designed for models using prescribed aerosol surface area density. This experiment will help to analyze H₂O and aerosol evolution, quantify the net radiative forcings, understand the impacts on mid-latitude and polar O₃ chemistry, and allow close comparisons with observations.

Original language	English
Pages (from-to)	5487-5512
Number of pages	26
Journal	Geoscientific Model Development
Volume	18
Issue number	17
DOIs	https://doi.org/10.5194/gmd-18-5487-2025
State	Published - 2025
Externally published	Yes

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10.5194/gmd-18-5487-2025

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Zhu, Y., Akiyoshi, H., Aquila, V., Asher, E., Bednarz, E. M., Bekki, S., Brühl, C., Butler, A. H., Case, P., Chabrillat, S., Chiodo, G., Clyne, M., Colarco, P. R., Dhomse, S., Falletti, L., Fleming, E., Johnson, B., Jörimann, A., Kovilakam, M., ... Zhuo, Z. (2025). Hunga Tonga–Hunga Ha'apai Volcano Impact Model Observation Comparison (HTHH-MOC) project: experiment protocol and model descriptions. Geoscientific Model Development, 18(17), 5487-5512. https://doi.org/10.5194/gmd-18-5487-2025

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title = "Hunga Tonga–Hunga Ha'apai Volcano Impact Model Observation Comparison (HTHH-MOC) project: experiment protocol and model descriptions",

abstract = "The 2022 Hunga volcanic eruption injected a significant amount of water vapor and a moderate amount of sulfur dioxide into the stratosphere, causing observable responses in the climate system. We have developed a model–observation comparison project to investigate the evolution of volcanic water and aerosols and their impacts on atmospheric dynamics, chemistry, and climate, using several state-of-the-art chemistry climate models. The project goals are (1) to evaluate the current chemistry–climate models to quantify their performance in comparison to observations and (2) to understand atmospheric responses in the Earth system after this exceptional event and investigate the potential impacts in the projected future. To achieve these goals, we designed specific experiments for direct comparisons to observations, for example from balloons and the Microwave Limb Sounder satellite instrument. Experiment 1 consists of two sets of free-running ensemble experiments from 2022 to 2031: one with fixed sea-surface temperatures and sea ice and one with coupled ocean. These experiments will help to understand the long-term evolution of water vapor and aerosols; quantify HTHH effects on stratospheric and mesospheric temperatures, dynamics, and transport; understand the impact of dynamic changes on ozone chemistry; quantify the net radiative forcings; and evaluate any surface climate impact. Experiment 2 is a nudged-run experiment from 2022 to 2023 using observed meteorology. To allow participation of more climate models with varying complexities of aerosol simulation, we include two sets of simulations in Experiment 2: Experiment 2a is designed for models with internally generated aerosol, while Experiment 2b is designed for models using prescribed aerosol surface area density. This experiment will help to analyze H2O and aerosol evolution, quantify the net radiative forcings, understand the impacts on mid-latitude and polar O3 chemistry, and allow close comparisons with observations.",

author = "Yunqian Zhu and Hideharu Akiyoshi and Valentina Aquila and Elizabeth Asher and Bednarz, \{Ewa M.\} and Slimane Bekki and Christoph Br{\"u}hl and Butler, \{Amy H.\} and Parker Case and Simon Chabrillat and Gabriel Chiodo and Margot Clyne and Colarco, \{Peter R.\} and Sandip Dhomse and Lola Falletti and Eric Fleming and Ben Johnson and Andrin J{\"o}rimann and Mahesh Kovilakam and Gerbrand Koren and Ales Kuchar and Nicolas Lebas and Qing Liang and Liu, \{Cheng Cheng\} and Graham Mann and Michael Manyin and Marion Marchand and Olaf Morgenstern and Paul Newman and Oman, \{Luke D.\} and {\O}sterstr{\o}m, \{Freja F.\} and Yifeng Peng and David Plummer and Ilaria Quaglia and William Randel and Samuel R{\'e}my and Takashi Sekiya and Stephen Steenrod and Timofei Sukhodolov and Simone Tilmes and Kostas Tsigaridis and Rei Ueyama and Daniele Visioni and Xinyue Wang and Shingo Watanabe and Yousuke Yamashita and Pengfei Yu and Wandi Yu and Jun Zhang and Zhihong Zhuo",

note = "Publisher Copyright: {\textcopyright} Author(s) 2025.",

year = "2025",

doi = "10.5194/gmd-18-5487-2025",

language = "English",

volume = "18",

pages = "5487--5512",

journal = "Geoscientific Model Development",

issn = "1991-959X",

publisher = "Copernicus Publications",

number = "17",

}

Zhu, Y, Akiyoshi, H, Aquila, V, Asher, E, Bednarz, EM, Bekki, S, Brühl, C, Butler, AH, Case, P, Chabrillat, S, Chiodo, G, Clyne, M, Colarco, PR, Dhomse, S, Falletti, L, Fleming, E, Johnson, B, Jörimann, A, Kovilakam, M, Koren, G, Kuchar, A, Lebas, N, Liang, Q, Liu, CC, Mann, G, Manyin, M, Marchand, M, Morgenstern, O, Newman, P, Oman, LD, Østerstrøm, FF, Peng, Y, Plummer, D, Quaglia, I, Randel, W, Rémy, S, Sekiya, T, Steenrod, S, Sukhodolov, T, Tilmes, S, Tsigaridis, K, Ueyama, R, Visioni, D, Wang, X, Watanabe, S, Yamashita, Y, Yu, P, Yu, W, Zhang, J & Zhuo, Z 2025, 'Hunga Tonga–Hunga Ha'apai Volcano Impact Model Observation Comparison (HTHH-MOC) project: experiment protocol and model descriptions', Geoscientific Model Development, vol. 18, no. 17, pp. 5487-5512. https://doi.org/10.5194/gmd-18-5487-2025

TY - JOUR

T1 - Hunga Tonga–Hunga Ha'apai Volcano Impact Model Observation Comparison (HTHH-MOC) project

T2 - experiment protocol and model descriptions

AU - Zhu, Yunqian

AU - Akiyoshi, Hideharu

AU - Aquila, Valentina

AU - Asher, Elizabeth

AU - Bednarz, Ewa M.

AU - Bekki, Slimane

AU - Brühl, Christoph

AU - Butler, Amy H.

AU - Case, Parker

AU - Chabrillat, Simon

AU - Chiodo, Gabriel

AU - Clyne, Margot

AU - Colarco, Peter R.

AU - Dhomse, Sandip

AU - Falletti, Lola

AU - Fleming, Eric

AU - Johnson, Ben

AU - Jörimann, Andrin

AU - Kovilakam, Mahesh

AU - Koren, Gerbrand

AU - Kuchar, Ales

AU - Lebas, Nicolas

AU - Liang, Qing

AU - Liu, Cheng Cheng

AU - Mann, Graham

AU - Manyin, Michael

AU - Marchand, Marion

AU - Morgenstern, Olaf

AU - Newman, Paul

AU - Oman, Luke D.

AU - Østerstrøm, Freja F.

AU - Peng, Yifeng

AU - Plummer, David

AU - Quaglia, Ilaria

AU - Randel, William

AU - Rémy, Samuel

AU - Sekiya, Takashi

AU - Steenrod, Stephen

AU - Sukhodolov, Timofei

AU - Tilmes, Simone

AU - Tsigaridis, Kostas

AU - Ueyama, Rei

AU - Visioni, Daniele

AU - Wang, Xinyue

AU - Watanabe, Shingo

AU - Yamashita, Yousuke

AU - Yu, Pengfei

AU - Yu, Wandi

AU - Zhang, Jun

AU - Zhuo, Zhihong

PY - 2025

Y1 - 2025

N2 - The 2022 Hunga volcanic eruption injected a significant amount of water vapor and a moderate amount of sulfur dioxide into the stratosphere, causing observable responses in the climate system. We have developed a model–observation comparison project to investigate the evolution of volcanic water and aerosols and their impacts on atmospheric dynamics, chemistry, and climate, using several state-of-the-art chemistry climate models. The project goals are (1) to evaluate the current chemistry–climate models to quantify their performance in comparison to observations and (2) to understand atmospheric responses in the Earth system after this exceptional event and investigate the potential impacts in the projected future. To achieve these goals, we designed specific experiments for direct comparisons to observations, for example from balloons and the Microwave Limb Sounder satellite instrument. Experiment 1 consists of two sets of free-running ensemble experiments from 2022 to 2031: one with fixed sea-surface temperatures and sea ice and one with coupled ocean. These experiments will help to understand the long-term evolution of water vapor and aerosols; quantify HTHH effects on stratospheric and mesospheric temperatures, dynamics, and transport; understand the impact of dynamic changes on ozone chemistry; quantify the net radiative forcings; and evaluate any surface climate impact. Experiment 2 is a nudged-run experiment from 2022 to 2023 using observed meteorology. To allow participation of more climate models with varying complexities of aerosol simulation, we include two sets of simulations in Experiment 2: Experiment 2a is designed for models with internally generated aerosol, while Experiment 2b is designed for models using prescribed aerosol surface area density. This experiment will help to analyze H2O and aerosol evolution, quantify the net radiative forcings, understand the impacts on mid-latitude and polar O3 chemistry, and allow close comparisons with observations.

AB - The 2022 Hunga volcanic eruption injected a significant amount of water vapor and a moderate amount of sulfur dioxide into the stratosphere, causing observable responses in the climate system. We have developed a model–observation comparison project to investigate the evolution of volcanic water and aerosols and their impacts on atmospheric dynamics, chemistry, and climate, using several state-of-the-art chemistry climate models. The project goals are (1) to evaluate the current chemistry–climate models to quantify their performance in comparison to observations and (2) to understand atmospheric responses in the Earth system after this exceptional event and investigate the potential impacts in the projected future. To achieve these goals, we designed specific experiments for direct comparisons to observations, for example from balloons and the Microwave Limb Sounder satellite instrument. Experiment 1 consists of two sets of free-running ensemble experiments from 2022 to 2031: one with fixed sea-surface temperatures and sea ice and one with coupled ocean. These experiments will help to understand the long-term evolution of water vapor and aerosols; quantify HTHH effects on stratospheric and mesospheric temperatures, dynamics, and transport; understand the impact of dynamic changes on ozone chemistry; quantify the net radiative forcings; and evaluate any surface climate impact. Experiment 2 is a nudged-run experiment from 2022 to 2023 using observed meteorology. To allow participation of more climate models with varying complexities of aerosol simulation, we include two sets of simulations in Experiment 2: Experiment 2a is designed for models with internally generated aerosol, while Experiment 2b is designed for models using prescribed aerosol surface area density. This experiment will help to analyze H2O and aerosol evolution, quantify the net radiative forcings, understand the impacts on mid-latitude and polar O3 chemistry, and allow close comparisons with observations.

UR - https://www.scopus.com/pages/publications/105033590486

U2 - 10.5194/gmd-18-5487-2025

DO - 10.5194/gmd-18-5487-2025

M3 - Article

AN - SCOPUS:105033590486

SN - 1991-959X

VL - 18

SP - 5487

EP - 5512

JO - Geoscientific Model Development

JF - Geoscientific Model Development

IS - 17

ER -

Hunga Tonga–Hunga Ha'apai Volcano Impact Model Observation Comparison (HTHH-MOC) project: experiment protocol and model descriptions

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