Multi-wave characteristics associated with January 15, 2022 Hunga-Tonga volcanic eruption: A global observation

IF 1.8 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS
M.S. Rose , P.S. Sunil , A. Sooraj , A.S. Sunil , Priyesh Kunnummal , K. Amal George , K.K. Ajith , Dhanya Thomas , V.K. Mini
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Abstract

The eruption of Hunga-Tonga Volcano on January 15, 2022 has stimulated a wide spectrum of atmospheric waves globally. To probe the surface deformation pattern, Sentinel-1 Synthetic Aperture Radar (SAR) data has been analyzed. It has been approximated that an overall area of about 2.47 square kilometres experienced deformation in conjunction with this event. To characterize the atmospheric wave propagation, barometric pressure data from 1814 stations distributed all around the globe have been examined. This study encompassed with the propagation characteristics of the waves over four zones including Indian and Polar regions for the first time using barometric data. Time-series observations indicate that the waves propagated globally multiple times. Within the Indian region, three minor arc passages and one major arc passage were identified. In Japan, two minor arc passages and one major arc were present. Conversely, in North America, both minor and major arc passages were detected, occurring a minimum of three times. Moreover, the attributes of these waves, such as their propagation speed and periodicity, were compared across these four regions. The estimated phase speed and periodicity fall within the ranges of approximately 291–314 m/s and 10–180 min, respectively including Polar Regions. These speed and periodicity measurements of the observed waves suggest that the dominant mode of wave propagation generated during the Tonga volcanic eruption is that of Lamb waves. In addition, a slower propagation phase speed of about 226.6 m/s was identified in Japan which corresponds to Pekeris mode of waves.

与 2022 年 1 月 15 日 Hunga-Tonga 火山喷发有关的多波特征:全球观测
2022 年 1 月 15 日雄加-通加火山的喷发在全球范围内激发了广泛的大气波浪。为了探测地表变形模式,对哨兵-1 号合成孔径雷达(SAR)数据进行了分析。据估计,与此次事件同时发生形变的总面积约为 2.47 平方公里。为了描述大气波的传播特征,我们研究了分布在全球各地的 1814 个站点的气压数据。这项研究首次利用气压数据研究了气压波在印度和极地等四个地区的传播特征。时间序列观测结果表明,海浪在全球范围内多次传播。在印度地区,发现了三个小弧形通道和一个大弧形通道。在日本,出现了两个小弧形通道和一个大弧形通道。相反,在北美洲,既发现了小弧传,也发现了大弧传,至少出现了三次。此外,还比较了这四个地区的这些波的属性,如传播速度和周期。包括极地区域在内,估计的相速度和周期范围分别约为 291-314 米/秒和 10-180 分钟。这些观测到的波速和周期测量结果表明,汤加火山爆发期间产生的主要波传播方式是兰姆波。此外,在日本还发现了一个较慢的传播相位速度,约为 226.6 米/秒,与 Pekeris 波模式相对应。
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来源期刊
Journal of Atmospheric and Solar-Terrestrial Physics
Journal of Atmospheric and Solar-Terrestrial Physics 地学-地球化学与地球物理
CiteScore
4.10
自引率
5.30%
发文量
95
审稿时长
6 months
期刊介绍: The Journal of Atmospheric and Solar-Terrestrial Physics (JASTP) is an international journal concerned with the inter-disciplinary science of the Earth''s atmospheric and space environment, especially the highly varied and highly variable physical phenomena that occur in this natural laboratory and the processes that couple them. The journal covers the physical processes operating in the troposphere, stratosphere, mesosphere, thermosphere, ionosphere, magnetosphere, the Sun, interplanetary medium, and heliosphere. Phenomena occurring in other "spheres", solar influences on climate, and supporting laboratory measurements are also considered. The journal deals especially with the coupling between the different regions. Solar flares, coronal mass ejections, and other energetic events on the Sun create interesting and important perturbations in the near-Earth space environment. The physics of such "space weather" is central to the Journal of Atmospheric and Solar-Terrestrial Physics and the journal welcomes papers that lead in the direction of a predictive understanding of the coupled system. Regarding the upper atmosphere, the subjects of aeronomy, geomagnetism and geoelectricity, auroral phenomena, radio wave propagation, and plasma instabilities, are examples within the broad field of solar-terrestrial physics which emphasise the energy exchange between the solar wind, the magnetospheric and ionospheric plasmas, and the neutral gas. In the lower atmosphere, topics covered range from mesoscale to global scale dynamics, to atmospheric electricity, lightning and its effects, and to anthropogenic changes.
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