3D diffusion of water in melt inclusion-bearing olivine phenocrysts
Olivine-hosted melt inclusions are an important archive of pre-eruptive processes such as magma storage, mixing and subsequent ascent through the crust. However, this record can be modified by post-entrapment diffusion of H+ through the olivine lattice. Existing studies often use spherical or 1D mod...
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sg-ntu-dr.10356-1747592024-04-15T15:30:52Z 3D diffusion of water in melt inclusion-bearing olivine phenocrysts Mutch, Euan J. F. Newcombe, Megan E. Rudge, John F. Asian School of the Environment Earth Observatory of Singapore Earth and Environmental Sciences Decompression rates Diffusion chronometry Olivine-hosted melt inclusions are an important archive of pre-eruptive processes such as magma storage, mixing and subsequent ascent through the crust. However, this record can be modified by post-entrapment diffusion of H+ through the olivine lattice. Existing studies often use spherical or 1D models to track melt inclusion dehydration that fail to account for complexities in geometry, diffusive anisotropy and sectioning effects. Here we develop a finite element 3D multiphase diffusion model for the dehydration of olivine-hosted melt inclusions that includes natural crystal geometries and multiple melt inclusions. We use our 3D model to test the reliability of simplified analytical and numerical models (1D and 2D) using magma ascent conditions from the 1977 eruption of Seguam volcano, Alaska. We find that 1D models underestimate melt inclusion water loss, typically by ∼30%, and thus underestimate magma decompression rates, by up to a factor of 5, when compared to the 3D models. An anisotropic analytical solution that we present performs well and recovers decompression rates within a factor of 2, in the situations in which it is valid. 3D models that include multiple melt inclusions show that inclusions can shield each other and reduce the amount of water loss upon ascent. This shielding effect depends on decompression rate, melt inclusion size, and crystallographic direction. Our modeling approach shows that factors such as 3D crystal geometry and melt inclusion configuration can play an important role in constraining accurate decompression rates and recovering water contents in natural magmatic systems. Published version EJFM acknowledges funding from a LDEO Postdoctoral Fellowship (UR005759), MEN acknowledges funding from NSF grant (2017897). 2024-04-09T05:11:59Z 2024-04-09T05:11:59Z 2024 Journal Article Mutch, E. J. F., Newcombe, M. E. & Rudge, J. F. (2024). 3D diffusion of water in melt inclusion-bearing olivine phenocrysts. Geochemistry, Geophysics, Geosystems, 25(3). https://dx.doi.org/10.1029/2023GC011365 1525-2027 https://hdl.handle.net/10356/174759 10.1029/2023GC011365 2-s2.0-85187128606 3 25 en Geochemistry, Geophysics, Geosystems © 2024 The Authors. Geochemistry, Geophysics, Geosystems published by Wiley Periodicals LLC on behalf of American Geophysical Union. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. application/pdf |
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Earth and Environmental Sciences Decompression rates Diffusion chronometry |
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Earth and Environmental Sciences Decompression rates Diffusion chronometry Mutch, Euan J. F. Newcombe, Megan E. Rudge, John F. 3D diffusion of water in melt inclusion-bearing olivine phenocrysts |
| description |
Olivine-hosted melt inclusions are an important archive of pre-eruptive processes such as magma storage, mixing and subsequent ascent through the crust. However, this record can be modified by post-entrapment diffusion of H+ through the olivine lattice. Existing studies often use spherical or 1D models to track melt inclusion dehydration that fail to account for complexities in geometry, diffusive anisotropy and sectioning effects. Here we develop a finite element 3D multiphase diffusion model for the dehydration of olivine-hosted melt inclusions that includes natural crystal geometries and multiple melt inclusions. We use our 3D model to test the reliability of simplified analytical and numerical models (1D and 2D) using magma ascent conditions from the 1977 eruption of Seguam volcano, Alaska. We find that 1D models underestimate melt inclusion water loss, typically by ∼30%, and thus underestimate magma decompression rates, by up to a factor of 5, when compared to the 3D models. An anisotropic analytical solution that we present performs well and recovers decompression rates within a factor of 2, in the situations in which it is valid. 3D models that include multiple melt inclusions show that inclusions can shield each other and reduce the amount of water loss upon ascent. This shielding effect depends on decompression rate, melt inclusion size, and crystallographic direction. Our modeling approach shows that factors such as 3D crystal geometry and melt inclusion configuration can play an important role in constraining accurate decompression rates and recovering water contents in natural magmatic systems. |
| author2 |
Asian School of the Environment |
| author_facet |
Asian School of the Environment Mutch, Euan J. F. Newcombe, Megan E. Rudge, John F. |
| format |
Article |
| author |
Mutch, Euan J. F. Newcombe, Megan E. Rudge, John F. |
| author_sort |
Mutch, Euan J. F. |
| title |
3D diffusion of water in melt inclusion-bearing olivine phenocrysts |
| title_short |
3D diffusion of water in melt inclusion-bearing olivine phenocrysts |
| title_full |
3D diffusion of water in melt inclusion-bearing olivine phenocrysts |
| title_fullStr |
3D diffusion of water in melt inclusion-bearing olivine phenocrysts |
| title_full_unstemmed |
3D diffusion of water in melt inclusion-bearing olivine phenocrysts |
| title_sort |
3d diffusion of water in melt inclusion-bearing olivine phenocrysts |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/174759 |
| _version_ |
1800916199820754944 |