Thermal State of the Guaymas Basin Derived From Gas Hydrate Bottom Simulating Reflections and Heat Flow Measurements

Sudipta Sarkar; Manuel Moser; Christian Berndt; Mechthild Doll; Christoph Böttner; Wu Cheng Chi; Dirk Klaeschen; Christophe Galerne; Jens Karstens; Sonja Geilert; C. Mortera-Gutierrez; Christian Hensen

doi:10.1029/2021JB023909

Thermal State of the Guaymas Basin Derived From Gas Hydrate Bottom Simulating Reflections and Heat Flow Measurements

Sudipta Sarkar^*
, Manuel Moser
, Christian Berndt
, Mechthild Doll
, Christoph Böttner
, Wu Cheng Chi
, Dirk Klaeschen
, Christophe Galerne
, Jens Karstens
, Sonja Geilert
, C. Mortera-Gutierrez
, Christian Hensen

^*Corresponding author for this work

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

Abstract

Seafloor heat flow provides information about the thermal evolution of the lithosphere, the magnitude and timing of volcanic activity, and hydrothermal circulation patterns. In the central Gulf of California, the Guaymas Basin is part of a young marginal spreading rift system that experiences high sedimentation (1–5 km/Myr) and widespread magmatic intrusions in the axial troughs and the off-axis regions. Heat flow variations record magmatic and sedimentary processes affecting the thermal evolution of the basin. Here, we present new seismic evidence of a widespread bottom-simulating reflection (BSR) in the northwestern Guaymas Basin. Using the BSR depths and thermal conductivity measurements, we determine geothermal gradient and surface heat flow variations. The BSR-derived heat flow values are less than the conductive lithospheric heat flow predictions for mid-oceanic ridges. They suggest that high sedimentation (0.3–1 km/Myr) suppresses the lithospheric heat flow. In the central and southeastern regions of the basin, the BSR-derived geothermal gradient increases as the intruded magmatic units reach shallower subsurface depths. Thermal modeling shows that recent (<5,000 years) igneous intrusions (<500 m below the seafloor) and associated fluid flow elevate the surface heat flow up to five times. BSR-derived geothermal gradients correlate little with the depth of the shallowest magmatic emplacements to the north, where the intrusions have already cooled for some time, and the associated hydrothermal activity is about to shut down.

Original language	English
Article number	e2021JB023909
Number of pages	20
Journal	Journal of Geophysical Research: Solid Earth
Volume	127
Issue number	8
DOIs	https://doi.org/10.1029/2021JB023909
Publication status	Published - Aug 2022
Externally published	Yes

Bibliographical note

Funding Information:
The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM‐LUCO group, especially to the UNAM‐ICMyL Tec. Francisco Ponce‐Nuñez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES‐I/2018/25) for infrastructure support and Shearwater Geoservices ( https://www.shearwatergeo.com ) and Paradigm/Emerson/AspenTech ( https://www.pdgm.com/ ) for providing seismic processing software and IHS Kingdom ( https://kingdom.ihs.com/ ) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments.

Funding Information:
The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM-LUCO group, especially to the UNAM-ICMyL Tec. Francisco Ponce-Nuñez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES-I/2018/25) for infrastructure support and Shearwater Geoservices (https://www.shearwatergeo.com) and Paradigm/Emerson/AspenTech (https://www.pdgm.com/) for providing seismic processing software and IHS Kingdom (https://kingdom.ihs.com/) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments.

Publisher Copyright:
© 2022. American Geophysical Union. All Rights Reserved.

Funding

The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM‐LUCO group, especially to the UNAM‐ICMyL Tec. Francisco Ponce‐Nuñez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES‐I/2018/25) for infrastructure support and Shearwater Geoservices ( https://www.shearwatergeo.com ) and Paradigm/Emerson/AspenTech ( https://www.pdgm.com/ ) for providing seismic processing software and IHS Kingdom ( https://kingdom.ihs.com/ ) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments. The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM-LUCO group, especially to the UNAM-ICMyL Tec. Francisco Ponce-Nuñez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES-I/2018/25) for infrastructure support and Shearwater Geoservices (https://www.shearwatergeo.com) and Paradigm/Emerson/AspenTech (https://www.pdgm.com/) for providing seismic processing software and IHS Kingdom (https://kingdom.ihs.com/) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments.

Keywords

gas hydrate
heat flow
hydrothermal vent
ocean spreading
sedimentation
sill intrusion

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10.1029/2021JB023909

Cite this

Sarkar, S., Moser, M., Berndt, C., Doll, M., Böttner, C., Chi, W. C., Klaeschen, D., Galerne, C., Karstens, J., Geilert, S., Mortera-Gutierrez, C., & Hensen, C. (2022). Thermal State of the Guaymas Basin Derived From Gas Hydrate Bottom Simulating Reflections and Heat Flow Measurements. Journal of Geophysical Research: Solid Earth, 127(8), Article e2021JB023909. https://doi.org/10.1029/2021JB023909

@article{8408b057e63b41edac6f57b1530895ad,

title = "Thermal State of the Guaymas Basin Derived From Gas Hydrate Bottom Simulating Reflections and Heat Flow Measurements",

abstract = "Seafloor heat flow provides information about the thermal evolution of the lithosphere, the magnitude and timing of volcanic activity, and hydrothermal circulation patterns. In the central Gulf of California, the Guaymas Basin is part of a young marginal spreading rift system that experiences high sedimentation (1–5 km/Myr) and widespread magmatic intrusions in the axial troughs and the off-axis regions. Heat flow variations record magmatic and sedimentary processes affecting the thermal evolution of the basin. Here, we present new seismic evidence of a widespread bottom-simulating reflection (BSR) in the northwestern Guaymas Basin. Using the BSR depths and thermal conductivity measurements, we determine geothermal gradient and surface heat flow variations. The BSR-derived heat flow values are less than the conductive lithospheric heat flow predictions for mid-oceanic ridges. They suggest that high sedimentation (0.3–1 km/Myr) suppresses the lithospheric heat flow. In the central and southeastern regions of the basin, the BSR-derived geothermal gradient increases as the intruded magmatic units reach shallower subsurface depths. Thermal modeling shows that recent (<5,000 years) igneous intrusions (<500 m below the seafloor) and associated fluid flow elevate the surface heat flow up to five times. BSR-derived geothermal gradients correlate little with the depth of the shallowest magmatic emplacements to the north, where the intrusions have already cooled for some time, and the associated hydrothermal activity is about to shut down.",

keywords = "gas hydrate, heat flow, hydrothermal vent, ocean spreading, sedimentation, sill intrusion",

author = "Sudipta Sarkar and Manuel Moser and Christian Berndt and Mechthild Doll and Christoph B{\"o}ttner and Chi, \{Wu Cheng\} and Dirk Klaeschen and Christophe Galerne and Jens Karstens and Sonja Geilert and C. Mortera-Gutierrez and Christian Hensen",

note = "Funding Information: The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM‐LUCO group, especially to the UNAM‐ICMyL Tec. Francisco Ponce‐Nu{\~n}ez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES‐I/2018/25) for infrastructure support and Shearwater Geoservices ( https://www.shearwatergeo.com ) and Paradigm/Emerson/AspenTech ( https://www.pdgm.com/ ) for providing seismic processing software and IHS Kingdom ( https://kingdom.ihs.com/ ) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments. Funding Information: The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM-LUCO group, especially to the UNAM-ICMyL Tec. Francisco Ponce-Nu{\~n}ez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES-I/2018/25) for infrastructure support and Shearwater Geoservices (https://www.shearwatergeo.com) and Paradigm/Emerson/AspenTech (https://www.pdgm.com/) for providing seismic processing software and IHS Kingdom (https://kingdom.ihs.com/) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments. Publisher Copyright: {\textcopyright} 2022. American Geophysical Union. All Rights Reserved.",

year = "2022",

month = aug,

doi = "10.1029/2021JB023909",

language = "English",

volume = "127",

journal = "Journal of Geophysical Research: Solid Earth",

issn = "2169-9313",

publisher = "John Wiley and Sons Inc.",

number = "8",

}

Sarkar, S, Moser, M, Berndt, C, Doll, M, Böttner, C, Chi, WC, Klaeschen, D, Galerne, C, Karstens, J, Geilert, S, Mortera-Gutierrez, C & Hensen, C 2022, 'Thermal State of the Guaymas Basin Derived From Gas Hydrate Bottom Simulating Reflections and Heat Flow Measurements', Journal of Geophysical Research: Solid Earth, vol. 127, no. 8, e2021JB023909. https://doi.org/10.1029/2021JB023909

TY - JOUR

T1 - Thermal State of the Guaymas Basin Derived From Gas Hydrate Bottom Simulating Reflections and Heat Flow Measurements

AU - Sarkar, Sudipta

AU - Moser, Manuel

AU - Berndt, Christian

AU - Doll, Mechthild

AU - Böttner, Christoph

AU - Chi, Wu Cheng

AU - Klaeschen, Dirk

AU - Galerne, Christophe

AU - Karstens, Jens

AU - Geilert, Sonja

AU - Mortera-Gutierrez, C.

AU - Hensen, Christian

N1 - Funding Information: The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM‐LUCO group, especially to the UNAM‐ICMyL Tec. Francisco Ponce‐Nuñez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES‐I/2018/25) for infrastructure support and Shearwater Geoservices ( https://www.shearwatergeo.com ) and Paradigm/Emerson/AspenTech ( https://www.pdgm.com/ ) for providing seismic processing software and IHS Kingdom ( https://kingdom.ihs.com/ ) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments. Funding Information: The captain and crew of RV Sonne provided essential support for the acquisition of the data during the SO241 cruise. The German Ministry of Science and Education (BMBF) (Grant No. 03G0241A) funded the cruise. MM is affiliated with the Centre of Excellence: Arctic Gas hydrate Environment and Climate (CAGE) and supported by the Norwegian Research Council Grant No. 223259. We thank the UNAM-LUCO group, especially to the UNAM-ICMyL Tec. Francisco Ponce-Nuñez, for sharing the multibeam bathymetric data of their campaigns GUAYRIV10 and GUAYMAS14. SS thanks DST FIST (Grant number SR/FST/ES-I/2018/25) for infrastructure support and Shearwater Geoservices (https://www.shearwatergeo.com) and Paradigm/Emerson/AspenTech (https://www.pdgm.com/) for providing seismic processing software and IHS Kingdom (https://kingdom.ihs.com/) for providing educational software licenses to the Indian Institute of Science Education and Research, Pune. We thank the Associate Editor, an anonymous reviewer and Warren Wood for their detailed and helpful comments. Publisher Copyright: © 2022. American Geophysical Union. All Rights Reserved.

PY - 2022/8

Y1 - 2022/8

N2 - Seafloor heat flow provides information about the thermal evolution of the lithosphere, the magnitude and timing of volcanic activity, and hydrothermal circulation patterns. In the central Gulf of California, the Guaymas Basin is part of a young marginal spreading rift system that experiences high sedimentation (1–5 km/Myr) and widespread magmatic intrusions in the axial troughs and the off-axis regions. Heat flow variations record magmatic and sedimentary processes affecting the thermal evolution of the basin. Here, we present new seismic evidence of a widespread bottom-simulating reflection (BSR) in the northwestern Guaymas Basin. Using the BSR depths and thermal conductivity measurements, we determine geothermal gradient and surface heat flow variations. The BSR-derived heat flow values are less than the conductive lithospheric heat flow predictions for mid-oceanic ridges. They suggest that high sedimentation (0.3–1 km/Myr) suppresses the lithospheric heat flow. In the central and southeastern regions of the basin, the BSR-derived geothermal gradient increases as the intruded magmatic units reach shallower subsurface depths. Thermal modeling shows that recent (<5,000 years) igneous intrusions (<500 m below the seafloor) and associated fluid flow elevate the surface heat flow up to five times. BSR-derived geothermal gradients correlate little with the depth of the shallowest magmatic emplacements to the north, where the intrusions have already cooled for some time, and the associated hydrothermal activity is about to shut down.

AB - Seafloor heat flow provides information about the thermal evolution of the lithosphere, the magnitude and timing of volcanic activity, and hydrothermal circulation patterns. In the central Gulf of California, the Guaymas Basin is part of a young marginal spreading rift system that experiences high sedimentation (1–5 km/Myr) and widespread magmatic intrusions in the axial troughs and the off-axis regions. Heat flow variations record magmatic and sedimentary processes affecting the thermal evolution of the basin. Here, we present new seismic evidence of a widespread bottom-simulating reflection (BSR) in the northwestern Guaymas Basin. Using the BSR depths and thermal conductivity measurements, we determine geothermal gradient and surface heat flow variations. The BSR-derived heat flow values are less than the conductive lithospheric heat flow predictions for mid-oceanic ridges. They suggest that high sedimentation (0.3–1 km/Myr) suppresses the lithospheric heat flow. In the central and southeastern regions of the basin, the BSR-derived geothermal gradient increases as the intruded magmatic units reach shallower subsurface depths. Thermal modeling shows that recent (<5,000 years) igneous intrusions (<500 m below the seafloor) and associated fluid flow elevate the surface heat flow up to five times. BSR-derived geothermal gradients correlate little with the depth of the shallowest magmatic emplacements to the north, where the intrusions have already cooled for some time, and the associated hydrothermal activity is about to shut down.

KW - gas hydrate

KW - heat flow

KW - hydrothermal vent

KW - ocean spreading

KW - sedimentation

KW - sill intrusion

UR - https://www.scopus.com/pages/publications/85137974883

U2 - 10.1029/2021JB023909

DO - 10.1029/2021JB023909

M3 - Article

AN - SCOPUS:85137974883

SN - 2169-9313

VL - 127

JO - Journal of Geophysical Research: Solid Earth

JF - Journal of Geophysical Research: Solid Earth

IS - 8

M1 - e2021JB023909

ER -

Thermal State of the Guaymas Basin Derived From Gas Hydrate Bottom Simulating Reflections and Heat Flow Measurements

Abstract

Bibliographical note

Funding

Keywords

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