An Amphibole Perspective on the Recent Magmatic Evolution of Mount St. Helens.

Keller, Franziska, Wanke, Maren, Kueter, Nico, Guillong, Marcel and Bachmann, Olivier (2024) An Amphibole Perspective on the Recent Magmatic Evolution of Mount St. Helens. Open Access Journal of Petrology, 65 (01). Art.Nr. egad093. DOI 10.1093/petrology/egad093.

[thumbnail of egad093.pdf]
Preview
Text
egad093.pdf - Published Version
Available under License Creative Commons: Attribution 4.0.

Download (3MB) | Preview
[thumbnail of web_material_egad093.zip] Archive
web_material_egad093.zip - Supplemental Material
Available under License Creative Commons: Attribution 4.0.

Download (149MB)

Supplementary data:

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 BP) 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 BP is associated with a change in reservoir conditions toward 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 MSH. 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 MSH’s volcanic record.

Document Type: Article
Keywords: amphibole, fractional crystallization, magmatic plumbing system, Mount St. Helens, volcanic evolution
Research affiliation: OceanRep > GEOMAR > D-DIR Directorate
Main POF Topic: PT8: Georesources
Refereed: Yes
Open Access Journal?: No
Publisher: Oxford University Press
Related URLs:
Date Deposited: 23 Feb 2024 06:51
Last Modified: 23 Feb 2024 10:50
URI: https://oceanrep.geomar.de/id/eprint/60019

Actions (login required)

View Item View Item