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Deep-sea gas hydrate mounds and chemosynthetic fauna discovered at 3640 m on the Molloy Ridge, Greenland Sea

Deep-sea gas hydrate mounds and chemosynthetic fauna discovered at 3640 m on the Molloy Ridge, Greenland Sea
Deep-sea gas hydrate mounds and chemosynthetic fauna discovered at 3640 m on the Molloy Ridge, Greenland Sea
Methane seepage at the seafloor can form gas hydrate and sustain chemosynthetic communities of deep-sea animals. Most known hydrate seeps occur shallower than 2000 m on continental slopes, whereas hydrothermal vents are found at greater depths along active spreading centres. Here we report the discovery of hydrate mounds with cold-seep fauna at 3640 m deep on the Molloy Ridge. The mounds display seafloor morphologies resulting from progressive stages of hydrate dissociation. Gas bubbles from the mounds rise to within 300 m of the ocean surface, and isotopic analysis shows the hydrates contain thermogenic gas. Crude oil sampled from the hydrate deposits indicates a young Miocene source rock formed in a fresh-brackish water paleo-environment. The hydrate mounds are inhabited by taxa including siboglinid and maldanid tubeworms, skeneid and rissoid snails, and melitid amphipods. Family-level composition of the fauna is similar to that of Arctic hydrothermal vents at similar depths, including the Jøtul vent field on the Knipovich Ridge, and less similar to nearby methane seeps at shallower depths. The overlap between seep and vent fauna in the Arctic has implications for understanding ecological connectivity across deep-sea habitats and assessing their vulnerability to future impacts from seafloor resource extraction in the region.
2041-1723
Panieri, Giuliana
c0559a7d-cf2c-4d0a-b61a-60889e963164
Copley, Jonathan T.
5f30e2a6-76c1-4150-9a42-dcfb8f5788ef
Linse, Katrin
74d7ddc0-74a1-4777-ac1d-3f39ae1935ad
Nye, Verity
e3688d01-623f-47b5-9a4c-7e49b16aa5a8
Ramirez-Llodra, Eva
eb365797-2452-4fed-9d48-1f78ace160ef
Argentino, Claudio
0699f58a-b728-40c8-8a4b-6b2c255dfe93
Ferré, Bénédicte
e9a7423b-c8b2-4cf7-9cb4-51506bf61bd5
Rogers, Alex D.
fb474198-f059-48f7-b637-74617b5023f6
Arctic Deep - Extreme24 consortium
Panieri, Giuliana
c0559a7d-cf2c-4d0a-b61a-60889e963164
Copley, Jonathan T.
5f30e2a6-76c1-4150-9a42-dcfb8f5788ef
Linse, Katrin
74d7ddc0-74a1-4777-ac1d-3f39ae1935ad
Nye, Verity
e3688d01-623f-47b5-9a4c-7e49b16aa5a8
Ramirez-Llodra, Eva
eb365797-2452-4fed-9d48-1f78ace160ef
Argentino, Claudio
0699f58a-b728-40c8-8a4b-6b2c255dfe93
Ferré, Bénédicte
e9a7423b-c8b2-4cf7-9cb4-51506bf61bd5
Rogers, Alex D.
fb474198-f059-48f7-b637-74617b5023f6

Arctic Deep - Extreme24 consortium (2025) Deep-sea gas hydrate mounds and chemosynthetic fauna discovered at 3640 m on the Molloy Ridge, Greenland Sea. Nature Communications, 16 (1), [11287]. (doi:10.1038/s41467-025-67165-x).

Record type: Article

Abstract

Methane seepage at the seafloor can form gas hydrate and sustain chemosynthetic communities of deep-sea animals. Most known hydrate seeps occur shallower than 2000 m on continental slopes, whereas hydrothermal vents are found at greater depths along active spreading centres. Here we report the discovery of hydrate mounds with cold-seep fauna at 3640 m deep on the Molloy Ridge. The mounds display seafloor morphologies resulting from progressive stages of hydrate dissociation. Gas bubbles from the mounds rise to within 300 m of the ocean surface, and isotopic analysis shows the hydrates contain thermogenic gas. Crude oil sampled from the hydrate deposits indicates a young Miocene source rock formed in a fresh-brackish water paleo-environment. The hydrate mounds are inhabited by taxa including siboglinid and maldanid tubeworms, skeneid and rissoid snails, and melitid amphipods. Family-level composition of the fauna is similar to that of Arctic hydrothermal vents at similar depths, including the Jøtul vent field on the Knipovich Ridge, and less similar to nearby methane seeps at shallower depths. The overlap between seep and vent fauna in the Arctic has implications for understanding ecological connectivity across deep-sea habitats and assessing their vulnerability to future impacts from seafloor resource extraction in the region.

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s41467-025-67165-x - Version of Record
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Accepted/In Press date: 24 November 2025
Published date: 17 December 2025
Additional Information: Publisher Copyright: © 2025. The Author(s).
Learn more about Ocean and Earth Science research Learn more about School of Ocean and Earth Science research

Identifiers

Local EPrints ID: 508235
URI: http://eprints.soton.ac.uk/id/eprint/508235
DOI: doi:10.1038/s41467-025-67165-x
ISSN: 2041-1723
PURE UUID: d0980bc9-e099-4257-8338-166c03b806cc
ORCID for Jonathan T. Copley: ORCID iD orcid.org/0000-0003-3333-4325

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Date deposited: 14 Jan 2026 18:16
Last modified: 15 Jan 2026 02:34

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Contributors

Author: Giuliana Panieri
Author: Jonathan T. Copley ORCID iD
Author: Katrin Linse
Author: Verity Nye
Author: Eva Ramirez-Llodra
Author: Claudio Argentino
Author: Bénédicte Ferré
Author: Alex D. Rogers
Corporate Author: Arctic Deep - Extreme24 consortium

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