Very-long-period seismicity associated with the 2009–2015 reawakening of Cotopaxi Volcano, Ecuador

IF 2.4 3区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Journal of Volcanology and Geothermal Research Pub Date : 2024-08-07 DOI:10.1016/j.jvolgeores.2024.108150

Indira Molina , Hiroyuki Kumagai , Mario Ruiz , Stephen Hernández , Patricia Mothes , Gabriela Arias , Joan Andújar

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引用次数: 0

Abstract

Cotopaxi is a large, ice-capped stratovolcano located in the Ecuadorian Andes. After 72 years of repose, Cotopaxi erupted on August 14, 2015. The precursory activity included long-period (LP) events followed by volcano-tectonic (VT) earthquakes, very-long-period events accompanying LP signals (VLP/LP events), tremor, deformation and SO₂ emissions. VLP/LP events were first observed at Cotopaxi in 2002, and persistently occurred from 2009 to 2014 and during the 2015 eruptions. Previous studies of the VLP/LP seismicity suggested that these events originated by repetitive volume changes in a crack due to degassing of water from magma at a depth of 2–3 km beneath the NE flank. Based on this interpretation, we estimated the magma volumes related to individual VLP/LP events from 2009 to 2015, which were systematically extracted from continuous seismic records of the Cotopaxi broadband seismic network. Based on the accumulated magma volume and the VLP/LP activity, our study is divided into seven periods (phases A − G), during which the magma supply rate significantly fluctuated. In phase E (June 1–July 27, 2015), before the eruptions, the magma supply rate increased. Degassing at the VLP source generated gas flows in the conduit and pre-eruptive tremor, gradually drying out a shallow hydrothermal system. In phase F (July 28–September 15, 2015), we estimated the highest magma supply rate, leading to magma fragmentation at the VLP source and eruptions accompanied by tremor. In phase G (September 16–December 29, 2015), the magma supply rate decreased, and overall eruptive activity, VLP/LP events, and tremor gradually waned. These results indicate that the VLP/LP events were likely generated by degassing from magma supplied to the VLP source through an intruded dike before and during the eruptions. The VLP/LP activity provides critical useful information about the magma supply rates that controlled eruptive and gas emission activity at Cotopaxi during this period and may help to constrain magma volumes during future reactivations.

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与 2009-2015 年厄瓜多尔科托帕希火山苏醒有关的超长周期地震活动

科托帕希火山是位于厄瓜多尔安第斯山脉的一座大型冰帽层火山。在沉睡了 72 年之后，科托帕希火山于 2015 年 8 月 14 日喷发。前兆活动包括长周期（LP）事件，随后是火山构造（VT）地震、伴随 LP 信号的超长周期事件（VLP/LP 事件）、震颤、形变和 SO 排放。VLP/LP 事件于 2002 年首次在科托帕希火山观测到，并在 2009 年至 2014 年以及 2015 年火山喷发期间持续发生。以前对 VLP/LP 地震的研究表明，这些事件的起因是东北侧 2-3 千米深处岩浆中的水脱气导致裂缝中的体积反复变化。根据这一解释，我们估算了 2009 年至 2015 年与单个 VLP/LP 事件相关的岩浆量，这些岩浆量是从科托帕希宽带地震网络的连续地震记录中系统提取的。根据累积的岩浆量和 VLP/LP 活动，我们的研究分为七个时期（A - G 阶段），在此期间岩浆供应率出现了显著波动。在 E 阶段（2015 年 6 月 1 日至 7 月 27 日），即喷发之前，岩浆供应率有所增加。VLP 源头的脱气作用在导管中产生了气流，并引发了喷发前的震颤，使浅层热液系统逐渐干涸。在F阶段（2015年7月28日至9月15日），我们估计岩浆供应率最高，导致VLP源的岩浆碎裂，喷发伴有震颤。在G阶段（2015年9月16日至12月29日），岩浆供应率下降，总体喷发活动、VLP/LP事件和震颤逐渐减弱。这些结果表明，VLP/LP事件很可能是在喷发前和喷发过程中通过侵入堤向VLP源供应岩浆的脱气作用产生的。VLP/LP活动提供了关于这一时期控制科托帕希火山爆发和气体排放活动的岩浆供应率的重要有用信息，并可能有助于在未来重新激活过程中限制岩浆量。

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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来源期刊

Journal of Volcanology and Geothermal Research 地学-地球科学综合

CiteScore

5.90

自引率

13.80%

发文量

183

审稿时长

19.7 weeks

期刊介绍： An international research journal with focus on volcanic and geothermal processes and their impact on the environment and society. Submission of papers covering the following aspects of volcanology and geothermal research are encouraged: (1) Geological aspects of volcanic systems: volcano stratigraphy, structure and tectonic influence; eruptive history; evolution of volcanic landforms; eruption style and progress; dispersal patterns of lava and ash; analysis of real-time eruption observations. (2) Geochemical and petrological aspects of volcanic rocks: magma genesis and evolution; crystallization; volatile compositions, solubility, and degassing; volcanic petrography and textural analysis. (3) Hydrology, geochemistry and measurement of volcanic and hydrothermal fluids: volcanic gas emissions; fumaroles and springs; crater lakes; hydrothermal mineralization. (4) Geophysical aspects of volcanic systems: physical properties of volcanic rocks and magmas; heat flow studies; volcano seismology, geodesy and remote sensing. (5) Computational modeling and experimental simulation of magmatic and hydrothermal processes: eruption dynamics; magma transport and storage; plume dynamics and ash dispersal; lava flow dynamics; hydrothermal fluid flow; thermodynamics of aqueous fluids and melts. (6) Volcano hazard and risk research: hazard zonation methodology, development of forecasting tools; assessment techniques for vulnerability and impact.