Hydrogen, single-carbon compounds, and thermal regime in the oceanic ultramafic-dominated lithosphere: Insights from a deep borehole on the Atlantis Massif

Susan Q. Lang; C. Geoffrey Wheat; Kristin L. Dickerson; Mark K. Reagan; Ivan P. Savov; Jordyn A. Robare; William J. Brazelton; Johanna Suhonen; Oscar Cavazos; Andrew McCaig; Peter Blum; Natsue Abe; Rémi Coltat; Jeremy R. Deans; Marguerite Godard; Barbara E. John; Frieder Klein; Rebecca Kuehn; Kuan Yu Lin; C. Johan Lissenberg; Haiyang Liu; Ethan L. Lopes; Toshio Nozaka; William Osborne; Andrew J. Parsons; Vamdev Pathak; Jessica Rodgers; Jeffrey S. Seewald; Kenneth W. Sims; Gordon Southam; Sean Sylva; Fengping Wang

doi:10.1016/j.gca.2025.09.024

Hydrogen, single-carbon compounds, and thermal regime in the oceanic ultramafic-dominated lithosphere: Insights from a deep borehole on the Atlantis Massif

Susan Q. Lang^*, C. Geoffrey Wheat, Kristin L. Dickerson, Mark K. Reagan, Ivan P. Savov, Jordyn A. Robare, William J. Brazelton, Johanna Suhonen, Oscar Cavazos, Andrew McCaig, Peter Blum, Natsue Abe, Rémi Coltat, Jeremy R. Deans, Marguerite Godard, Barbara E. John, Frieder Klein, Rebecca Kuehn, Kuan Yu Lin, C. Johan LissenbergHaiyang Liu, Ethan L. Lopes, Toshio Nozaka, William Osborne, Andrew J. Parsons, Vamdev Pathak, Jessica Rodgers, Jeffrey S. Seewald, Kenneth W. Sims, Gordon Southam, Sean Sylva, Fengping Wang

^*Corresponding author for this work

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Abstract

Water that flows through permeable ultramafic rocks produces high abundances of molecular hydrogen (H₂), methane (CH₄), and other small organic molecules. Such products can fuel life in the rocky subseafloor, be extracted for energy, and may have played a role in pre-biological chemical synthesis on early Earth or other planetary bodies. The International Ocean Discovery Program drilled a new 1268-m-deep borehole (U1601C) into serpentinized mantle with minor gabbroic rocks on the Atlantis Massif, ∼800-m north of the Lost City hydrothermal field (30°N, Mid-Atlantic Ridge). Measured temperatures of the disturbed borehole reached 91.3 °C, and equilibrated temperatures of the deepest section are estimated to be between 110 – 140 °C. Water collected every ∼ 5-m during drilling operations had H₂concentrations that were regularly > 200 nM and spiked to > 10 µM at multiple depths. In these waters, carbon monoxide was only present in deeper, hotter sections, and potentially associated with gabbroic intrusions into the peridotite host. Open borehole fluids were sampled after drilling and samples recovered from the deepest portion contained elevated short-lived 222-Radon and strontium isotope ratios similar to Lost City fluids, pointing to the presence of in situ subseafloor formation waters that have equilibrated with the host rock. The deepest samples were actively degassing upon recovery and contained 740 ± 360 µM H₂, 340 ± 36 µM CH₄, and 25.5 µM ∑formate (= formate and formic acid). The shallowest fluids from the open borehole also contain micromolar H₂and ∑formate concentrations, the presence of which cannot be attributed to the upward migration of the deeper, higher concentration fluids.We interpret these data as reflecting two distinct and interconnected regimes of fluid flow and composition. Deep waters that are channelized along faults, lithologic contacts, and other high permeability pathways host high H₂and CH₄concentrations plus micromolar ∑formate that closely mirror the chemistry and isotopic signatures of LCHF vent fluids. Pervasive fluid flow permeates the mesh texture and microfracture network of the serpentinized peridotite and sustains H₂and ∑formate even in the shallowest subseafloor intervals at mild temperatures. These findings demonstrate that both focused and pervasive fluid flow contribute to the transport, and potentially the generation, of reduced volatiles and C1 compounds within the Atlantis Massif.

Original language	English
Pages (from-to)	84-104
Number of pages	21
Journal	Geochimica et Cosmochimica Acta
Volume	408
Early online date	20 Sept 2025
DOIs	https://doi.org/10.1016/j.gca.2025.09.024
Publication status	Published - 1 Nov 2025

ASJC Scopus subject areas

Geochemistry and Petrology

Keywords

Abiotic organic carbon
Expedition 399
Formation waters
Hydrogen
International Ocean Discovery Program
Methane
Ocean worlds
Organic acids
Prebiotic precursors
Serpentinization
Site 1601

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10.1016/j.gca.2025.09.024

Lang_et_al_2025_PREPRINTAccepted author manuscript, 2.98 MBLicence: CC BY-NC-ND

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Lang, S. Q., Wheat, C. G., Dickerson, K. L., Reagan, M. K., Savov, I. P., Robare, J. A., Brazelton, W. J., Suhonen, J., Cavazos, O., McCaig, A., Blum, P., Abe, N., Coltat, R., Deans, J. R., Godard, M., John, B. E., Klein, F., Kuehn, R., Lin, K. Y., ... Wang, F. (2025). Hydrogen, single-carbon compounds, and thermal regime in the oceanic ultramafic-dominated lithosphere: Insights from a deep borehole on the Atlantis Massif. Geochimica et Cosmochimica Acta, 408, 84-104. https://doi.org/10.1016/j.gca.2025.09.024

@article{8ec6a621de134c2c8eef097041091a83,

title = "Hydrogen, single-carbon compounds, and thermal regime in the oceanic ultramafic-dominated lithosphere: Insights from a deep borehole on the Atlantis Massif",

abstract = "Water that flows through permeable ultramafic rocks produces high abundances of molecular hydrogen (H2), methane (CH4), and other small organic molecules. Such products can fuel life in the rocky subseafloor, be extracted for energy, and may have played a role in pre-biological chemical synthesis on early Earth or other planetary bodies. The International Ocean Discovery Program drilled a new 1268-m-deep borehole (U1601C) into serpentinized mantle with minor gabbroic rocks on the Atlantis Massif, ∼800-m north of the Lost City hydrothermal field (30°N, Mid-Atlantic Ridge). Measured temperatures of the disturbed borehole reached 91.3 °C, and equilibrated temperatures of the deepest section are estimated to be between 110 – 140 °C. Water collected every ∼ 5-m during drilling operations had H2concentrations that were regularly > 200 nM and spiked to > 10 µM at multiple depths. In these waters, carbon monoxide was only present in deeper, hotter sections, and potentially associated with gabbroic intrusions into the peridotite host. Open borehole fluids were sampled after drilling and samples recovered from the deepest portion contained elevated short-lived 222-Radon and strontium isotope ratios similar to Lost City fluids, pointing to the presence of in situ subseafloor formation waters that have equilibrated with the host rock. The deepest samples were actively degassing upon recovery and contained 740 ± 360 µM H2, 340 ± 36 µM CH4, and 25.5 µM ∑formate (= formate and formic acid). The shallowest fluids from the open borehole also contain micromolar H2and ∑formate concentrations, the presence of which cannot be attributed to the upward migration of the deeper, higher concentration fluids.We interpret these data as reflecting two distinct and interconnected regimes of fluid flow and composition. Deep waters that are channelized along faults, lithologic contacts, and other high permeability pathways host high H2and CH4concentrations plus micromolar ∑formate that closely mirror the chemistry and isotopic signatures of LCHF vent fluids. Pervasive fluid flow permeates the mesh texture and microfracture network of the serpentinized peridotite and sustains H2and ∑formate even in the shallowest subseafloor intervals at mild temperatures. These findings demonstrate that both focused and pervasive fluid flow contribute to the transport, and potentially the generation, of reduced volatiles and C1 compounds within the Atlantis Massif.",

keywords = "Abiotic organic carbon, Expedition 399, Formation waters, Hydrogen, International Ocean Discovery Program, Methane, Ocean worlds, Organic acids, Prebiotic precursors, Serpentinization, Site 1601",

author = "Lang, \{Susan Q.\} and Wheat, \{C. Geoffrey\} and Dickerson, \{Kristin L.\} and Reagan, \{Mark K.\} and Savov, \{Ivan P.\} and Robare, \{Jordyn A.\} and Brazelton, \{William J.\} and Johanna Suhonen and Oscar Cavazos and Andrew McCaig and Peter Blum and Natsue Abe and R{\'e}mi Coltat and Deans, \{Jeremy R.\} and Marguerite Godard and John, \{Barbara E.\} and Frieder Klein and Rebecca Kuehn and Lin, \{Kuan Yu\} and Lissenberg, \{C. Johan\} and Haiyang Liu and Lopes, \{Ethan L.\} and Toshio Nozaka and William Osborne and Parsons, \{Andrew J.\} and Vamdev Pathak and Jessica Rodgers and Seewald, \{Jeffrey S.\} and Sims, \{Kenneth W.\} and Gordon Southam and Sean Sylva and Fengping Wang",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies.",

year = "2025",

month = nov,

day = "1",

doi = "10.1016/j.gca.2025.09.024",

language = "English",

volume = "408",

pages = "84--104",

journal = "Geochimica et Cosmochimica Acta",

issn = "0016-7037",

publisher = "Elsevier Ltd.",

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Lang, SQ, Wheat, CG, Dickerson, KL, Reagan, MK, Savov, IP, Robare, JA, Brazelton, WJ, Suhonen, J, Cavazos, O, McCaig, A, Blum, P, Abe, N, Coltat, R, Deans, JR, Godard, M, John, BE, Klein, F, Kuehn, R, Lin, KY, Lissenberg, CJ, Liu, H, Lopes, EL, Nozaka, T, Osborne, W, Parsons, AJ, Pathak, V, Rodgers, J, Seewald, JS, Sims, KW, Southam, G, Sylva, S & Wang, F 2025, 'Hydrogen, single-carbon compounds, and thermal regime in the oceanic ultramafic-dominated lithosphere: Insights from a deep borehole on the Atlantis Massif', Geochimica et Cosmochimica Acta, vol. 408, pp. 84-104. https://doi.org/10.1016/j.gca.2025.09.024

TY - JOUR

T1 - Hydrogen, single-carbon compounds, and thermal regime in the oceanic ultramafic-dominated lithosphere: Insights from a deep borehole on the Atlantis Massif

AU - Lang, Susan Q.

AU - Wheat, C. Geoffrey

AU - Dickerson, Kristin L.

AU - Reagan, Mark K.

AU - Savov, Ivan P.

AU - Robare, Jordyn A.

AU - Brazelton, William J.

AU - Suhonen, Johanna

AU - Cavazos, Oscar

AU - McCaig, Andrew

AU - Blum, Peter

AU - Abe, Natsue

AU - Coltat, Rémi

AU - Deans, Jeremy R.

AU - Godard, Marguerite

AU - John, Barbara E.

AU - Klein, Frieder

AU - Kuehn, Rebecca

AU - Lin, Kuan Yu

AU - Lissenberg, C. Johan

AU - Liu, Haiyang

AU - Lopes, Ethan L.

AU - Nozaka, Toshio

AU - Osborne, William

AU - Parsons, Andrew J.

AU - Pathak, Vamdev

AU - Rodgers, Jessica

AU - Seewald, Jeffrey S.

AU - Sims, Kenneth W.

AU - Southam, Gordon

AU - Sylva, Sean

AU - Wang, Fengping

PY - 2025/11/1

Y1 - 2025/11/1

N2 - Water that flows through permeable ultramafic rocks produces high abundances of molecular hydrogen (H2), methane (CH4), and other small organic molecules. Such products can fuel life in the rocky subseafloor, be extracted for energy, and may have played a role in pre-biological chemical synthesis on early Earth or other planetary bodies. The International Ocean Discovery Program drilled a new 1268-m-deep borehole (U1601C) into serpentinized mantle with minor gabbroic rocks on the Atlantis Massif, ∼800-m north of the Lost City hydrothermal field (30°N, Mid-Atlantic Ridge). Measured temperatures of the disturbed borehole reached 91.3 °C, and equilibrated temperatures of the deepest section are estimated to be between 110 – 140 °C. Water collected every ∼ 5-m during drilling operations had H2concentrations that were regularly > 200 nM and spiked to > 10 µM at multiple depths. In these waters, carbon monoxide was only present in deeper, hotter sections, and potentially associated with gabbroic intrusions into the peridotite host. Open borehole fluids were sampled after drilling and samples recovered from the deepest portion contained elevated short-lived 222-Radon and strontium isotope ratios similar to Lost City fluids, pointing to the presence of in situ subseafloor formation waters that have equilibrated with the host rock. The deepest samples were actively degassing upon recovery and contained 740 ± 360 µM H2, 340 ± 36 µM CH4, and 25.5 µM ∑formate (= formate and formic acid). The shallowest fluids from the open borehole also contain micromolar H2and ∑formate concentrations, the presence of which cannot be attributed to the upward migration of the deeper, higher concentration fluids.We interpret these data as reflecting two distinct and interconnected regimes of fluid flow and composition. Deep waters that are channelized along faults, lithologic contacts, and other high permeability pathways host high H2and CH4concentrations plus micromolar ∑formate that closely mirror the chemistry and isotopic signatures of LCHF vent fluids. Pervasive fluid flow permeates the mesh texture and microfracture network of the serpentinized peridotite and sustains H2and ∑formate even in the shallowest subseafloor intervals at mild temperatures. These findings demonstrate that both focused and pervasive fluid flow contribute to the transport, and potentially the generation, of reduced volatiles and C1 compounds within the Atlantis Massif.

AB - Water that flows through permeable ultramafic rocks produces high abundances of molecular hydrogen (H2), methane (CH4), and other small organic molecules. Such products can fuel life in the rocky subseafloor, be extracted for energy, and may have played a role in pre-biological chemical synthesis on early Earth or other planetary bodies. The International Ocean Discovery Program drilled a new 1268-m-deep borehole (U1601C) into serpentinized mantle with minor gabbroic rocks on the Atlantis Massif, ∼800-m north of the Lost City hydrothermal field (30°N, Mid-Atlantic Ridge). Measured temperatures of the disturbed borehole reached 91.3 °C, and equilibrated temperatures of the deepest section are estimated to be between 110 – 140 °C. Water collected every ∼ 5-m during drilling operations had H2concentrations that were regularly > 200 nM and spiked to > 10 µM at multiple depths. In these waters, carbon monoxide was only present in deeper, hotter sections, and potentially associated with gabbroic intrusions into the peridotite host. Open borehole fluids were sampled after drilling and samples recovered from the deepest portion contained elevated short-lived 222-Radon and strontium isotope ratios similar to Lost City fluids, pointing to the presence of in situ subseafloor formation waters that have equilibrated with the host rock. The deepest samples were actively degassing upon recovery and contained 740 ± 360 µM H2, 340 ± 36 µM CH4, and 25.5 µM ∑formate (= formate and formic acid). The shallowest fluids from the open borehole also contain micromolar H2and ∑formate concentrations, the presence of which cannot be attributed to the upward migration of the deeper, higher concentration fluids.We interpret these data as reflecting two distinct and interconnected regimes of fluid flow and composition. Deep waters that are channelized along faults, lithologic contacts, and other high permeability pathways host high H2and CH4concentrations plus micromolar ∑formate that closely mirror the chemistry and isotopic signatures of LCHF vent fluids. Pervasive fluid flow permeates the mesh texture and microfracture network of the serpentinized peridotite and sustains H2and ∑formate even in the shallowest subseafloor intervals at mild temperatures. These findings demonstrate that both focused and pervasive fluid flow contribute to the transport, and potentially the generation, of reduced volatiles and C1 compounds within the Atlantis Massif.

KW - Abiotic organic carbon

KW - Expedition 399

KW - Formation waters

KW - Hydrogen

KW - International Ocean Discovery Program

KW - Methane

KW - Ocean worlds

KW - Organic acids

KW - Prebiotic precursors

KW - Serpentinization

KW - Site 1601

UR - https://www.scopus.com/pages/publications/105018013167

UR - https://pearl.plymouth.ac.uk/gees-research/1501/

U2 - 10.1016/j.gca.2025.09.024

DO - 10.1016/j.gca.2025.09.024

M3 - Article

AN - SCOPUS:105018013167

SN - 0016-7037

VL - 408

SP - 84

EP - 104

JO - Geochimica et Cosmochimica Acta

JF - Geochimica et Cosmochimica Acta

ER -

Hydrogen, single-carbon compounds, and thermal regime in the oceanic ultramafic-dominated lithosphere: Insights from a deep borehole on the Atlantis Massif

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