Magma flow patterns in dikes: observations from analogue experiments
We conducted analogue experiments to examine flux-driven and buoyancy-driven magma ascent, which included a series of isothermal experiments and thermal, solidification-prone experiments. We measured the internal flow using 2D particle image velocimetry, which indicates that buoyancy has a strong co...
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sg-ntu-dr.10356-1696452023-07-31T15:30:41Z Magma flow patterns in dikes: observations from analogue experiments Pansino, Stephen Emadzadeh, Adel Taisne, Benoit Asian School of the Environment Earth Observatory of Singapore Science::Geology Analogue Experiments Crystal Growth We conducted analogue experiments to examine flux-driven and buoyancy-driven magma ascent, which included a series of isothermal experiments and thermal, solidification-prone experiments. We measured the internal flow using 2D particle image velocimetry, which indicates that buoyancy has a strong control on the flow pattern of isothermal dikes. Dikes that are not buoyant (likely driven by source pressure) take on a circulating pattern, while buoyant dikes assume an ascending flow pattern. Solidification modifies the flow field so that flow is confined to the dike's upper head region. The lower tail becomes mostly solidified, with a narrow conduit connecting the source to the head. We interpret that this conduit acts as a high velocity point source to the head, promoting a circulating flow pattern, even as the dike becomes buoyant. We then perform particle tracking velocimetry on several particles to illustrate the complexity of their paths. In a circulating flow pattern, particles rise to the top of the dike, descend near the lateral edge, and then are drawn back into the upward flow. In an ascending pattern, particles ascend slightly faster than the propagation velocity, and therefore are pushed to the side as they approach the upper tip. In erupting dikes, particles simply flow to the vent. In the context of crystal growth in magmatic dikes, these results suggest that crystal growth patterns (e.g., normal or oscillatory zoning) can reflect the magma flow pattern, and potentially the driving forces. Ministry of Education (MOE) National Research Foundation (NRF) Published version This research is supported by the National Research Foundation Singapore (award NRF2015-NRF-ISF001-2437) and the Singapore Ministry of Education under the Research Centres of Excellence initiative. S. Pansino was funded by a Newton International Fellowship (award NIF\R1\202137), supported by the Royal Society. 2023-07-27T08:40:44Z 2023-07-27T08:40:44Z 2023 Journal Article Pansino, S., Emadzadeh, A. & Taisne, B. (2023). Magma flow patterns in dikes: observations from analogue experiments. Journal of Geophysical Research: Solid Earth, 128(3), e2022JB025463-. https://dx.doi.org/10.1029/2022JB025463 2169-9313 https://hdl.handle.net/10356/169645 10.1029/2022JB025463 2-s2.0-85151071661 3 128 e2022JB025463 en NRF2015-NRF-ISF001-2437 Journal of Geophysical Research: Solid Earth © 2023 The Authors.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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Science::Geology Analogue Experiments Crystal Growth Pansino, Stephen Emadzadeh, Adel Taisne, Benoit Magma flow patterns in dikes: observations from analogue experiments |
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We conducted analogue experiments to examine flux-driven and buoyancy-driven magma ascent, which included a series of isothermal experiments and thermal, solidification-prone experiments. We measured the internal flow using 2D particle image velocimetry, which indicates that buoyancy has a strong control on the flow pattern of isothermal dikes. Dikes that are not buoyant (likely driven by source pressure) take on a circulating pattern, while buoyant dikes assume an ascending flow pattern. Solidification modifies the flow field so that flow is confined to the dike's upper head region. The lower tail becomes mostly solidified, with a narrow conduit connecting the source to the head. We interpret that this conduit acts as a high velocity point source to the head, promoting a circulating flow pattern, even as the dike becomes buoyant. We then perform particle tracking velocimetry on several particles to illustrate the complexity of their paths. In a circulating flow pattern, particles rise to the top of the dike, descend near the lateral edge, and then are drawn back into the upward flow. In an ascending pattern, particles ascend slightly faster than the propagation velocity, and therefore are pushed to the side as they approach the upper tip. In erupting dikes, particles simply flow to the vent. In the context of crystal growth in magmatic dikes, these results suggest that crystal growth patterns (e.g., normal or oscillatory zoning) can reflect the magma flow pattern, and potentially the driving forces. |
| author2 |
Asian School of the Environment |
| author_facet |
Asian School of the Environment Pansino, Stephen Emadzadeh, Adel Taisne, Benoit |
| format |
Article |
| author |
Pansino, Stephen Emadzadeh, Adel Taisne, Benoit |
| author_sort |
Pansino, Stephen |
| title |
Magma flow patterns in dikes: observations from analogue experiments |
| title_short |
Magma flow patterns in dikes: observations from analogue experiments |
| title_full |
Magma flow patterns in dikes: observations from analogue experiments |
| title_fullStr |
Magma flow patterns in dikes: observations from analogue experiments |
| title_full_unstemmed |
Magma flow patterns in dikes: observations from analogue experiments |
| title_sort |
magma flow patterns in dikes: observations from analogue experiments |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/169645 |
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1773551287673028608 |