Constraints on ground deformation processes at the Tulu Moye volcanic complex, Main Ethiopian Rift
Constraints on ground deformation processes at the Tulu Moye volcanic complex, Main Ethiopian Rift
Tulu Moye is an actively deforming volcanic complex with a geothermal field in the Main Ethiopian Rift. We use InSAR between 2014 and 2022, integrated with other geophysical data, to investigate the temporal and spatial characteristics of the deformation signal in the area, and to model its source. Velocity maps and time series analysis show a deformation signal consistent with uplift at a velocity of up to 50 mm/yr in the satellite Line-of-Sight (LOS) in 2014–2017, then decreasing to 12 mm/yr until 2022. The centre of deformation is located about 10 km west of a main geothermal drilling site at Tulu Moye, between the Bora, Berecha, and Tulu Moye volcanoes, with a NW-SE elongation direction. Our best-fit model suggests that the deformation is caused by an 8.7 km by 1.2 km sill situated ∼7.7 km below the surface (∼5.9 km below sea-level), elongate in the N54°W direction and dipping S11°W, and experienced an average velocity of volume change of ∼8.9 × 106 m3/yr in 2014–2017. The surface projection of the sill overlaps with local transverse faults and hydrothermal manifestations. The sill is ∼1–2 km below clusters of microseismic swarms and a region of high resistivity, both indicating hydrothermal fluid flow. The location and geometry of the sill correlates with the upper edge of high conductivity interpreted as a zone of partial melt, and we therefore attribute the uplift at the Tulu Moye volcanic complex to inflow of magma in the sill. We also suggest that the transverse caldera rims faults may restrict magma flow, and also facilitate both vertical and lateral hydrothermal fluid flow.
Deformation, Ethiopian rift, Geothermal, InSAR, Tulu Moye
Kebede, Birhan A.
e6f29910-2138-47b1-936d-997767700325
Pagli, Carolina
290edb22-712b-4563-a868-af4c21fdb6b0
Sigmundsson, Freysteinn
c4909556-6d7f-4628-aa24-3bda56a63cc2
Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
La Rosa, Alessandro
3443c440-23fe-437e-b908-80f6b923c4ba
Guðbrandsson, Snorri
2cfbb8cf-3896-4efc-bdd1-06eec521fbc0
17 May 2023
Kebede, Birhan A.
e6f29910-2138-47b1-936d-997767700325
Pagli, Carolina
290edb22-712b-4563-a868-af4c21fdb6b0
Sigmundsson, Freysteinn
c4909556-6d7f-4628-aa24-3bda56a63cc2
Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
La Rosa, Alessandro
3443c440-23fe-437e-b908-80f6b923c4ba
Guðbrandsson, Snorri
2cfbb8cf-3896-4efc-bdd1-06eec521fbc0
Kebede, Birhan A., Pagli, Carolina, Sigmundsson, Freysteinn, Keir, Derek, La Rosa, Alessandro and Guðbrandsson, Snorri
(2023)
Constraints on ground deformation processes at the Tulu Moye volcanic complex, Main Ethiopian Rift.
Journal of Volcanology and Geothermal Research, 438, [107810].
(doi:10.1016/j.jvolgeores.2023.107810).
Abstract
Tulu Moye is an actively deforming volcanic complex with a geothermal field in the Main Ethiopian Rift. We use InSAR between 2014 and 2022, integrated with other geophysical data, to investigate the temporal and spatial characteristics of the deformation signal in the area, and to model its source. Velocity maps and time series analysis show a deformation signal consistent with uplift at a velocity of up to 50 mm/yr in the satellite Line-of-Sight (LOS) in 2014–2017, then decreasing to 12 mm/yr until 2022. The centre of deformation is located about 10 km west of a main geothermal drilling site at Tulu Moye, between the Bora, Berecha, and Tulu Moye volcanoes, with a NW-SE elongation direction. Our best-fit model suggests that the deformation is caused by an 8.7 km by 1.2 km sill situated ∼7.7 km below the surface (∼5.9 km below sea-level), elongate in the N54°W direction and dipping S11°W, and experienced an average velocity of volume change of ∼8.9 × 106 m3/yr in 2014–2017. The surface projection of the sill overlaps with local transverse faults and hydrothermal manifestations. The sill is ∼1–2 km below clusters of microseismic swarms and a region of high resistivity, both indicating hydrothermal fluid flow. The location and geometry of the sill correlates with the upper edge of high conductivity interpreted as a zone of partial melt, and we therefore attribute the uplift at the Tulu Moye volcanic complex to inflow of magma in the sill. We also suggest that the transverse caldera rims faults may restrict magma flow, and also facilitate both vertical and lateral hydrothermal fluid flow.
Text
1-s2.0-S0377027323000677-main
- Accepted Manuscript
Text
1-s2.0-S0377027323000677-main
- Proof
Restricted to Repository staff only
Request a copy
Text
Kebede_2023_accepted
More information
Accepted/In Press date: 23 April 2023
e-pub ahead of print date: 28 April 2023
Published date: 17 May 2023
Additional Information:
Funding Information:
This work is part of PhD project under the XXXVII cycle of the Dottorato Regionale Pegaso in Earth Sciences; and supported by the Ministero Università e Ricerca (MiUR) with the National Operational Program (PON)-2014-2020 Action IV.5 “PhDs on green issues”. We would like to thank Reykjavik Geothermal Ltd. for allowing Birhan Abera Kebede to conduct her internship program. We acknowledge support by the ESA (European Space Agency) NoR (Network of Resources) initiative for Geohazards Exploitation Platform (G-TEP). We particularly thank Hervé Caumont and Michele Sica from Terradue for the support with G-TEP.
Publisher Copyright:
© 2023
Keywords:
Deformation, Ethiopian rift, Geothermal, InSAR, Tulu Moye
Identifiers
Local EPrints ID: 478318
URI: http://eprints.soton.ac.uk/id/eprint/478318
ISSN: 0377-0273
PURE UUID: d70e1a63-6f63-4387-b3ac-9ebabadf4f3e
Catalogue record
Date deposited: 27 Jun 2023 17:37
Last modified: 28 Apr 2024 04:01
Export record
Altmetrics
Contributors
Author:
Birhan A. Kebede
Author:
Carolina Pagli
Author:
Freysteinn Sigmundsson
Author:
Alessandro La Rosa
Author:
Snorri Guðbrandsson
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
