Seismic record of a long duration dispersive signal after the 15 January 2022 Hunga-Tonga eruption

Seismica Pub Date : 2023-11-29 DOI:10.26443/seismica.v2i2.1033

Jordi Diaz

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Abstract

Data acquired by broadband seismic stations distributed around the world are used to document the exceptionally long duration signal from the tsunami-associated gravity wave that followed the January 2022 Hunga-Tonga eruption. The first arrivals of this wave, with a frequency of around 2 mHz, are recorded at the time the tsunami arrives to each station, but the highest recorded frequencies, which reach 40 mHz, arrive 5 days later at some sites, following the prediction of a gravity wave originating at the Hunga-Tonga region and traveling in deep water. This dispersive signal is detected in most of the stations located in the Pacific Ocean basin and its coasts, but also in the Indian Ocean, Antarctica, and some stations in North America located hundreds of kilometers from the coastline. The signal is compared with the data gathered after earthquakes that have produced large tsunamis, showing that the seismic records from the Hunga-Tonga eruption are very different. Following the hypothesis pointed out by Omira et al 2023, we propose that the origin of this exceptional characteristic is due to the interaction between the tsunami and atmospheric waves that travel a little faster.

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2022 年 1 月 15 日洪加-通加火山爆发后的长时频散信号地震记录

分布在世界各地的宽带地震台获得的数据用于记录 2022 年 1 月洪加-通加火山爆发后海啸相关重力波产生的超长持续时间信号。在海啸到达每个观测站时，记录到频率约为 2 mHz 的重力波首次到达，但在一些观测站记录到的最高频率（达到 40 mHz）是在 5 天之后到达的，这与预测的重力波发源于洪加-通加地区并在深水中传播的情况一致。位于太平洋海盆及其沿岸的大多数站点，以及印度洋、南极洲和北美洲距海岸线数百公里的一些站点，都探测到了这一分散信号。该信号与产生大海啸的地震后收集的数据进行了比较，结果显示，洪加-通加火山爆发的地震记录有很大不同。根据 Omira 等人 2023 年提出的假设，我们认为这一特殊特征的起源是由于海啸与传播速度稍快的大气波浪之间的相互作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Seismica

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