A Review of the Source Characteristics and Physical Mechanisms of Very Long Period (VLP) Seismic Signals at Active Volcanoes

IF 4.9 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
K. I. Konstantinou
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Abstract

Very Long Period (VLP) signals with periods longer than 2 s may occur during eruptive or quiet phases at volcanoes of all types (shield and stratovolcanoes with calderas, as well as other stratovolcanoes) and are inherently connected to fluid movement within the plumbing system. This is supported by observations at several volcanoes that indicate a correlation between gas emissions and VLPs, as well as deformation episodes due to melt accumulation and migration that are followed by the occurrence of VLPs. Moment tensors of VLPs are usually characterized by large volumetric components of either positive or negative sign along with possibly the presence of single forces that may result from the exchange of linear momentum between the seismic source and the Earth. VLPs may occur during a variety of volcanological processes such as caldera collapse, phreatic eruptions, vulcanian eruptions, strombolian activity, and rockfalls at lava lakes. Physical mechanisms that can generate VLPs include the inflation and deflation of magma chambers and cracks, the movement of gas slugs through conduits, and the restoration of gravitational equilibrium in the plumbing system after explosive degassing or rockfalls in lava lakes. Our understanding of VLPs is expected to greatly improve in the future by the use of new instrumentation, such as Distributed Acoustic Sensing, that will provide a much denser temporal and spatial sampling of the seismic wavefield. This vast quantity of data will then require time efficient and objective processing that can be achieved through the use of machine learning algorithms.

Abstract Image

活动火山甚长周期(VLP)地震信号的震源特征及物理机制研究进展
周期超过 2 秒的甚长周期(VLP)信号可能出现在各种类型的火山(盾状火山和有破火山口的层火山,以及其他层火山)的喷发或平静阶段,并且与管道系统内的流体运动有内在联系。对几座火山的观测证实了这一点,观测结果表明气体排放与 VLPs 之间存在相关性,熔体堆积和迁移导致的变形事件也与 VLPs 的出现有关。VLP 的动量张量通常具有正负符号的大体积分量,同时可能存在地震源与地球之间线性动量交换产生的单个力。VLP 可能发生在各种火山过程中,如火山口崩塌、喷发、火山喷发、血栓活动和熔岩湖的岩崩。产生VLPs的物理机制包括岩浆室和裂缝的膨胀和放气、气体蛞蝓通过导管的运动以及熔岩湖爆炸性脱气或岩崩后管道系统重力平衡的恢复。通过使用分布式声学传感等新仪器,对地震波场进行更密集的时间和空间采样,我们对 VLPs 的了解有望在未来得到极大改善。大量的数据需要高效、客观的处理,这可以通过使用机器学习算法来实现。
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来源期刊
Surveys in Geophysics
Surveys in Geophysics 地学-地球化学与地球物理
CiteScore
10.00
自引率
10.90%
发文量
64
审稿时长
4.5 months
期刊介绍: Surveys in Geophysics publishes refereed review articles on the physical, chemical and biological processes occurring within the Earth, on its surface, in its atmosphere and in the near-Earth space environment, including relations with other bodies in the solar system. Observations, their interpretation, theory and modelling are covered in papers dealing with any of the Earth and space sciences.
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