An amphibole perspective on the recent magmatic evolution of Mount St. Helens

IF 3.5 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Franziska Keller, Maren Wanke, Nico Kueter, Marcel Guillong, Olivier Bachmann
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Abstract

Compositional variations of amphibole stratigraphically recovered from multiple eruptions at a given volcano have a great potential to archive long-term magmatic processes in its crustal plumbing system. Calcic amphibole is a ubiquitous yet chemically and texturally diverse mineral at Mount St. Helens (MSH), where it occurs in dacites and in co-magmatic enclaves throughout the Spirit Lake stage (last ~4000 years of eruptive history). It forms three populations with distinct geochemical trends in key major and trace elements, which are subdivided into a high-Al (11–14.5 wt% Al2O3), a medium-Al (10–12.5 wt% Al2O3), and a low-Al (7.5–10 wt% Al2O3) amphibole population. The oldest investigated tephra record (Smith Creek period, 3900–3300 years B.P.) yields a bimodal amphibole distribution in which lower-crustal, high-Al amphibole cores (crystallized dominantly from basaltic andesite to andesite melts) and upper-crustal, low-Al amphibole rims (crystallized from rhyolitic melt) document occasional recharge of a shallow silicic mush by a more mafic melt from a lower-crustal reservoir. The sudden appearance of medium-Al amphiboles enriched in incompatible trace elements in eruptive periods younger than 2900 years B.P. is associated with a change in reservoir conditions towards hotter and drier magmas, which indicates recharge of the shallow silicic reservoir by basaltic melt enriched in incompatible elements. Deep-crystallizing, high-Al amphibole, however, appears mostly unaffected by such incompatible-element-enriched basaltic recharge, suggesting that these basalts bypass the lower crustal reservoir. This could be the result of the eastward offset position of the lower crustal reservoir relative to the upper crustal storage zone underneath the MSH edifice. Amphibole has proven to be a sensitive geochemical archive for uncovering storage conditions of magmas at Mount St. Helens. In agreement with geophysical observations, storage and differentiation have occurred in two main zones: an upper crustal and lower crustal reservoir (the lower one being chemically less evolved). The upper crustal silicic reservoir, offset to the west of the lower crustal reservoir, has captured compositionally unusual mafic recharge (drier, hotter, and enriched in incompatible trace elements in comparison to the typical parental magmas in the region), resulting in an increased chemical diversity of amphiboles and their carrier intermediate magmas, in the last ~3000 years of Mount St. Helens’s volcanic record.
圣海伦火山近期岩浆演化的闪石视角
从某一火山的多次喷发地层中回收的闪石成分变化具有很大的潜力,可以记录其地壳管道系统中长期的岩浆过程。在圣海伦火山(MSH),钙闪石是一种无处不在,但在化学和质地上却多种多样的矿物,它出现在整个灵湖阶段(最后约 4000 年的喷发历史)的英安岩和共岩浆岩飞地中。它形成了三个群体,其主要元素和微量元素的地球化学趋势截然不同,可细分为高铝(11-14.5 wt% Al2O3)、中铝(10-12.5 wt% Al2O3)和低铝(7.5-10 wt% Al2O3)闪石群体。最古老的研究记录(史密斯溪时期,公元前 3900-3300 年)显示了双峰闪石的分布,其中低地壳、高铝闪石核心(主要由玄武安山岩到安山岩熔体结晶而成)和上地壳、低铝闪石边缘(由流纹岩熔体结晶而成)记录了来自低地壳储层的较黑云母熔体偶尔对浅硅质淤泥的补给。在小于公元前2900年的喷发期,突然出现富含不相容微量元素的中铝闪石,这与储层条件向更热、更干燥的岩浆转变有关,表明富含不相容元素的玄武岩熔体对浅硅质储层的补给。然而,深结晶的高铝闪石似乎大多不受这种富含不相容元素的玄武岩补给的影响,这表明这些玄武岩绕过了下地壳储层。这可能是由于下地壳储层相对于 MSH 大厦下的上地壳储层区的位置向东偏移造成的。事实证明,闪石是揭示圣海伦火山岩浆储存条件的敏感地球化学档案。与地球物理观测结果一致,岩浆的贮存和分化主要发生在两个区域:上地壳和下地壳贮存区(下地壳的化学演化程度较低)。上地壳硅质储层偏向于下地壳储层的西面,捕获了成分异常的岩浆补给(与该地区典型的母岩浆相比,更干燥、更热、富含不相容微量元素),导致在圣海伦火山记录的过去约3000年中,闪石及其载体中间岩浆的化学多样性增加。
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来源期刊
Journal of Petrology
Journal of Petrology 地学-地球化学与地球物理
CiteScore
6.90
自引率
12.80%
发文量
117
审稿时长
12 months
期刊介绍: The Journal of Petrology provides an international forum for the publication of high quality research in the broad field of igneous and metamorphic petrology and petrogenesis. Papers published cover a vast range of topics in areas such as major element, trace element and isotope geochemistry and geochronology applied to petrogenesis; experimental petrology; processes of magma generation, differentiation and emplacement; quantitative studies of rock-forming minerals and their paragenesis; regional studies of igneous and meta morphic rocks which contribute to the solution of fundamental petrological problems; theoretical modelling of petrogenetic processes.
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