Evidence for crustal brines and deep fluid infiltration in an oceanic transform fault

Christine Chesley; Rob Evans; Jessica M. Warren; Andrew C. Gase; Jacob Perez; Christopher Armerding; Hannah Brewer; Paige Koenig; Eric Attias; Bailey L. Fluegel; Jae Deok Kim; Natalie Hummel; Katherine Enright; Emilia Topp-Johnson; Margaret S. Boettcher

doi:10.1126/sciadv.adu3661

Evidence for crustal brines and deep fluid infiltration in an oceanic transform fault

Christine Chesley, Rob Evans, Jessica M. Warren, Andrew C. Gase, Jacob Perez, Christopher Armerding, Hannah Brewer, Paige Koenig, Eric Attias, Bailey L. Fluegel, Jae Deok Kim, Natalie Hummel, Katherine Enright, Emilia Topp-Johnson, Margaret S. Boettcher

Geosciences Department

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Although oceanic transform faults (OTFs) are ubiquitous plate boundaries, the geological processes occurring along these systems remain underexplored. The Gofar OTF of the East Pacific Rise has gained attention due to its predictable, yet enigmatic, earthquake cycle. Here, we present results from the first ever controlled-source electromagnetic survey of an OTF, which sampled Gofar. We find that the fault is characterized by a subvertical conductor, which extends into the lower crust and thus implies deep fluid penetration. We also image subhorizontal crustal conductors distributed asymmetrically about the fault. We interpret these subhorizontal anomalies as crustal brines, and we suggest that the high permeability of the fault combined with the influence of melt in the transform domain can promote hydrothermal circulation and brine condensation at OTFs.

Original language	English
Article number	eadu3661
Pages (from-to)	eadu3661
Journal	Science Advances
Volume	11
Issue number	15
DOIs	https://doi.org/10.1126/sciadv.adu3661
State	Published - 11 Apr 2025

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Chesley, C., Evans, R., Warren, J. M., Gase, A. C., Perez, J., Armerding, C., Brewer, H., Koenig, P., Attias, E., Fluegel, B. L., Kim, J. D., Hummel, N., Enright, K., Topp-Johnson, E., & Boettcher, M. S. (2025). Evidence for crustal brines and deep fluid infiltration in an oceanic transform fault. Science Advances, 11(15), eadu3661. Article eadu3661. https://doi.org/10.1126/sciadv.adu3661

@article{e7cf2d0a8e4348d98b645bbe2216f3b0,

title = "Evidence for crustal brines and deep fluid infiltration in an oceanic transform fault",

abstract = "Although oceanic transform faults (OTFs) are ubiquitous plate boundaries, the geological processes occurring along these systems remain underexplored. The Gofar OTF of the East Pacific Rise has gained attention due to its predictable, yet enigmatic, earthquake cycle. Here, we present results from the first ever controlled-source electromagnetic survey of an OTF, which sampled Gofar. We find that the fault is characterized by a subvertical conductor, which extends into the lower crust and thus implies deep fluid penetration. We also image subhorizontal crustal conductors distributed asymmetrically about the fault. We interpret these subhorizontal anomalies as crustal brines, and we suggest that the high permeability of the fault combined with the influence of melt in the transform domain can promote hydrothermal circulation and brine condensation at OTFs.",

author = "Christine Chesley and Rob Evans and Warren, \{Jessica M.\} and Gase, \{Andrew C.\} and Jacob Perez and Christopher Armerding and Hannah Brewer and Paige Koenig and Eric Attias and Fluegel, \{Bailey L.\} and Kim, \{Jae Deok\} and Natalie Hummel and Katherine Enright and Emilia Topp-Johnson and Boettcher, \{Margaret S.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 The Authors, some rights reserved.",

year = "2025",

month = apr,

day = "11",

doi = "10.1126/sciadv.adu3661",

language = "English",

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Chesley, C, Evans, R, Warren, JM, Gase, AC, Perez, J, Armerding, C, Brewer, H, Koenig, P, Attias, E, Fluegel, BL, Kim, JD, Hummel, N, Enright, K, Topp-Johnson, E & Boettcher, MS 2025, 'Evidence for crustal brines and deep fluid infiltration in an oceanic transform fault', Science Advances, vol. 11, no. 15, eadu3661, pp. eadu3661. https://doi.org/10.1126/sciadv.adu3661

TY - JOUR

T1 - Evidence for crustal brines and deep fluid infiltration in an oceanic transform fault

AU - Chesley, Christine

AU - Evans, Rob

AU - Warren, Jessica M.

AU - Gase, Andrew C.

AU - Perez, Jacob

AU - Armerding, Christopher

AU - Brewer, Hannah

AU - Koenig, Paige

AU - Attias, Eric

AU - Fluegel, Bailey L.

AU - Kim, Jae Deok

AU - Hummel, Natalie

AU - Enright, Katherine

AU - Topp-Johnson, Emilia

AU - Boettcher, Margaret S.

PY - 2025/4/11

Y1 - 2025/4/11

N2 - Although oceanic transform faults (OTFs) are ubiquitous plate boundaries, the geological processes occurring along these systems remain underexplored. The Gofar OTF of the East Pacific Rise has gained attention due to its predictable, yet enigmatic, earthquake cycle. Here, we present results from the first ever controlled-source electromagnetic survey of an OTF, which sampled Gofar. We find that the fault is characterized by a subvertical conductor, which extends into the lower crust and thus implies deep fluid penetration. We also image subhorizontal crustal conductors distributed asymmetrically about the fault. We interpret these subhorizontal anomalies as crustal brines, and we suggest that the high permeability of the fault combined with the influence of melt in the transform domain can promote hydrothermal circulation and brine condensation at OTFs.

AB - Although oceanic transform faults (OTFs) are ubiquitous plate boundaries, the geological processes occurring along these systems remain underexplored. The Gofar OTF of the East Pacific Rise has gained attention due to its predictable, yet enigmatic, earthquake cycle. Here, we present results from the first ever controlled-source electromagnetic survey of an OTF, which sampled Gofar. We find that the fault is characterized by a subvertical conductor, which extends into the lower crust and thus implies deep fluid penetration. We also image subhorizontal crustal conductors distributed asymmetrically about the fault. We interpret these subhorizontal anomalies as crustal brines, and we suggest that the high permeability of the fault combined with the influence of melt in the transform domain can promote hydrothermal circulation and brine condensation at OTFs.

UR - https://www.scopus.com/pages/publications/105002689146

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DO - 10.1126/sciadv.adu3661

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C2 - 40215302

AN - SCOPUS:105002689146

VL - 11

SP - eadu3661

JO - Science Advances

JF - Science Advances

IS - 15

M1 - eadu3661

ER -

Evidence for crustal brines and deep fluid infiltration in an oceanic transform fault

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