Utilizing Thermal Demagnetization Events to Evaluate Volcanic Unrest and the Prospects for Eruption Forecasting

IF 0.2 Q4 GEOGRAPHY, PHYSICAL

Journal of Geography-Chigaku Zasshi Pub Date : 2021-12-25 DOI:10.5026/jgeography.130.771

T. Hashimoto

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引用次数: 3

Abstract

― Abstract Volcanoes with shallow hydrothermal systems are often accompanied by background volcanic activity such as fumarolic activity, microseismicity, and ground deformation even in the non-eruptive phase. When elevated, they are said to be in a state of “unrest.” It is not difﬁcult to imagine that such events of unrest reﬂect changes in the state of the shallow hydrothermal system beneath a volcano. However, there is currently no method by which these events can be used to quantitatively evaluate eruption imminency or predict eruption intensity based on physical and/or chemical models. A potentially useful application of such unrest events for probabilistically forecasting eruptions is discussed. First, the method proposed by Hashimoto et al . （ 2019 ） for compil-ing and evaluating the sources of unrest events, such as thermal demagnetization, is described. Then, the volcanic unrest index （ VUI ） of Potter et al . （ 2015a ） is proposed as another key tool. Finally, a concept is proposed for integrating the VUI and the unrest data to make probabilistically forecasting eruptions feasible. Also described is a recent attempt to introduce the VUI for evaluating a volcano in Japan. Information on sources of unrest in the form of the scatter plot of Hashimoto et al . （ 2019 ） can be used as one of the rating criteria on the VUI worksheet. The key idea is to divide the source diagram into regions based on the probability of posterior eruptions given unrest events and to assign VUI scores to these regions. Such a procedure may augment the VUI’s function, partially enabling probability-based eruption forecasting. Irrespective of whether the VUI is applied or not, it is essential to obtain temporally homogeneous monitoring data during both eruptive and non-eruptive periods for a quantitative evaluation of unrest events. Surveys and analyses carried out regularly over long time periods also play an equally important role. Therefore, to realize of probabilistic eruption forecasting, it is fundamentally important that monitoring networks are run properly and the data are shared appropriately.

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利用热消磁事件评价火山不稳定性及火山喷发预报的前景

具有浅层热液系统的火山通常伴随着背景火山活动，如火山喷发活动、微地震活动和即使在非喷发阶段的地面变形。当被提升时，他们被称为处于“不稳定”状态。不难想象，这样的动荡事件反映了火山下浅层热液系统状态的变化。然而，目前还没有方法可以利用这些事件来定量评估喷发的迫近性或基于物理和/或化学模型预测喷发强度。讨论了这种动乱事件在概率预测喷发方面的潜在有用应用。首先，由Hashimoto等人提出的方法。(2019)，用于编译和评估动荡事件的来源，如热退磁，进行了描述。然后，波特等人的火山动荡指数(VUI)。(2015a)是另一个关键工具。最后，提出了一种整合VUI和动乱数据的概念，使火山喷发的概率预测成为可能。还介绍了最近尝试引入VUI来评估日本的火山。以Hashimoto等人的散点图形式提供动乱来源的信息。(2019)可以作为VUI工作表上的评级标准之一。关键思想是根据动乱事件后爆发的概率将源图划分为区域，并为这些区域分配VUI分数。这样的程序可以增强VUI的功能，部分实现基于概率的火山爆发预测。无论是否应用VUI，在爆发和非爆发期间获得时间上均匀的监测数据对于动乱事件的定量评估都是至关重要的。长期定期进行的调查和分析也起着同样重要的作用。因此，要实现概率喷发预报，监测网络的正常运行和数据的合理共享至关重要。

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来源期刊

Journal of Geography-Chigaku Zasshi GEOGRAPHY, PHYSICAL-

CiteScore

1.50

自引率

33.30%

发文量