Atmospheric and Ionospheric Responses to Hunga-Tonga Volcano Eruption Simulated by WACCM-X

H. L. Liu; W. Wang; J. D. Huba; P. H. Lauritzen; F. Vitt

doi:10.1029/2023GL103682

Atmospheric and Ionospheric Responses to Hunga-Tonga Volcano Eruption Simulated by WACCM-X

H. L. Liu, W. Wang, J. D. Huba, P. H. Lauritzen, F. Vitt

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32 Scopus citations

Abstract

High-resolution Whole Atmosphere Community Climate Model with thermosphere/ionosphere extension is used to simulate the responses to the Hunga-Tonga volcano eruption on 15 January 2022. Global propagation of the Lamb wave L’₀ and L’₁ pseudomodes are reproduced in the simulation, with the exponential growth of wave amplitudes with altitudes. The wavefront is vertical up to the lower thermosphere, and tilts outward above. These features are consistent with theoretical results. With simulated surface pressure perturbation agreeing with observations (∼100–250 Pa), thermospheric wind perturbations over 100 ms⁻¹ are comparable with reported satellite and ground-based observations. Traveling ionospheric disturbances in the total electron contents from the simulation show good agreement with observations, including magnitude and propagating speed and evidence of conjugacy in the first 1–2 hr after eruption. Conjugacy in E × B drift, on the other hand, is more persistent.

Original language	English
Article number	e2023GL103682
Journal	Geophysical Research Letters
Volume	50
Issue number	10
DOIs	https://doi.org/10.1029/2023GL103682
State	Published - May 28 2023

Keywords

Lamb wave
atmosphere coupling
ionosphere
thermosphere
volcano eruption

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10.1029/2023GL103682

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title = "Atmospheric and Ionospheric Responses to Hunga-Tonga Volcano Eruption Simulated by WACCM-X",

abstract = "High-resolution Whole Atmosphere Community Climate Model with thermosphere/ionosphere extension is used to simulate the responses to the Hunga-Tonga volcano eruption on 15 January 2022. Global propagation of the Lamb wave L{\textquoteright}0 and L{\textquoteright}1 pseudomodes are reproduced in the simulation, with the exponential growth of wave amplitudes with altitudes. The wavefront is vertical up to the lower thermosphere, and tilts outward above. These features are consistent with theoretical results. With simulated surface pressure perturbation agreeing with observations (∼100–250 Pa), thermospheric wind perturbations over 100 ms−1 are comparable with reported satellite and ground-based observations. Traveling ionospheric disturbances in the total electron contents from the simulation show good agreement with observations, including magnitude and propagating speed and evidence of conjugacy in the first 1–2 hr after eruption. Conjugacy in E × B drift, on the other hand, is more persistent.",

keywords = "Lamb wave, atmosphere coupling, ionosphere, thermosphere, volcano eruption",

author = "Liu, \{H. L.\} and W. Wang and Huba, \{J. D.\} and Lauritzen, \{P. H.\} and F. Vitt",

note = "Publisher Copyright: {\textcopyright} 2023. The Authors.",

year = "2023",

month = may,

day = "28",

doi = "10.1029/2023GL103682",

language = "English",

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T1 - Atmospheric and Ionospheric Responses to Hunga-Tonga Volcano Eruption Simulated by WACCM-X

AU - Liu, H. L.

AU - Wang, W.

AU - Huba, J. D.

AU - Lauritzen, P. H.

AU - Vitt, F.

PY - 2023/5/28

Y1 - 2023/5/28

N2 - High-resolution Whole Atmosphere Community Climate Model with thermosphere/ionosphere extension is used to simulate the responses to the Hunga-Tonga volcano eruption on 15 January 2022. Global propagation of the Lamb wave L’0 and L’1 pseudomodes are reproduced in the simulation, with the exponential growth of wave amplitudes with altitudes. The wavefront is vertical up to the lower thermosphere, and tilts outward above. These features are consistent with theoretical results. With simulated surface pressure perturbation agreeing with observations (∼100–250 Pa), thermospheric wind perturbations over 100 ms−1 are comparable with reported satellite and ground-based observations. Traveling ionospheric disturbances in the total electron contents from the simulation show good agreement with observations, including magnitude and propagating speed and evidence of conjugacy in the first 1–2 hr after eruption. Conjugacy in E × B drift, on the other hand, is more persistent.

AB - High-resolution Whole Atmosphere Community Climate Model with thermosphere/ionosphere extension is used to simulate the responses to the Hunga-Tonga volcano eruption on 15 January 2022. Global propagation of the Lamb wave L’0 and L’1 pseudomodes are reproduced in the simulation, with the exponential growth of wave amplitudes with altitudes. The wavefront is vertical up to the lower thermosphere, and tilts outward above. These features are consistent with theoretical results. With simulated surface pressure perturbation agreeing with observations (∼100–250 Pa), thermospheric wind perturbations over 100 ms−1 are comparable with reported satellite and ground-based observations. Traveling ionospheric disturbances in the total electron contents from the simulation show good agreement with observations, including magnitude and propagating speed and evidence of conjugacy in the first 1–2 hr after eruption. Conjugacy in E × B drift, on the other hand, is more persistent.

KW - Lamb wave

KW - atmosphere coupling

KW - ionosphere

KW - thermosphere

KW - volcano eruption

UR - https://www.scopus.com/pages/publications/85160436949

U2 - 10.1029/2023GL103682

DO - 10.1029/2023GL103682

M3 - Article

AN - SCOPUS:85160436949

SN - 0094-8276

VL - 50

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 10

M1 - e2023GL103682

ER -

Atmospheric and Ionospheric Responses to Hunga-Tonga Volcano Eruption Simulated by WACCM-X

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Keywords

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