Methane-flow system within the Nyegga pockmark field, offshore mid-Norway

Stéphanie Dupré; Jean-Paul Foucher; Catherine Pierre; Carole Decker; Graham Westbrook; Stephan Ker; Karine Olu; Jean-Pierre Donval; Jean-Luc Charlou; Marie-Madeleine Blanc-Valleron; Hervé Nouzé

doi:10.3389/feart.2023.1250619

Methane-flow system within the Nyegga pockmark field, offshore mid-Norway

Stéphanie Dupré^*, Jean-Paul Foucher, Catherine Pierre, Carole Decker, Graham Westbrook, Stephan Ker, Karine Olu, Jean-Pierre Donval, Jean-Luc Charlou, Marie-Madeleine Blanc-Valleron, Hervé Nouzé

^*Corresponding author for this work

Earth and Environmental Sciences

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

16 Downloads (Pure)

Abstract

We investigated fluid seepage within the Nyegga pockmark field (600–900 m water depths) off mid-Norway from Remotely Operated Vehicle dives at the so-called CNE sites (CNE01 to CNE17). The seafloor morphology of some of these features corresponds to pockmarks and adjacent ridges, with the latter being the focus of present seepage activity. These structures are underlain by chimneys above a gas-charged zone with, in some cases, a substantial body of hydrate-invaded sediment (down to 1.3 s in two-way travel time at CNE03). Present-day methane-rich fluid seepage through the seabed is indicated by chemosynthetic fauna, in particular Siboglinidae polychaetes (Oligobrachia haakonmobiensis webbi and Sclerolinum contortum), microbial mats and associated Rissoidae gastropod (Alvania sp.) grazers, and confirmed by measured in situ bottom-water methane anomalies, up to 2,130 nL/L. No free-gas bubble emissions were observed or acoustically identified. The presence of authigenic carbonates reveals past seepage with very low δ¹³C values (down to −58‰) indicating that the major source of carbon was methane carried by the venting fluids. The ages of major periods of methane venting are provided by vesicomyid bivalve shells (Isorropodon nyeggaensis) present in two sedimentary layers, 14,930 and 15,500 14C yr BP (ca. 17,238 and 17,952 cal yr BP), respectively, corresponding to the time of Melt Water Pulse IA. The seafloor morphology and pattern of seepage -chemosynthetic fauna and microbial mat distribution and dissolved methane concentration-are remarkably heterogeneous. Pore-water chemistry profiles in a gravity core taken only 40 m from major seepage sites indicate no seepage and anaerobic methane oxidation at a sub-bottom depth of about 2 m. Present-day seepage from the studied pockmark-chimney fluid-flow system charged with gas hydrate is dominated by the advection of methane solution in pore water. Some of this methane could result from the dissolution of hydrate in the chimney, most of which would have formed during an earlier period (post-LGM times) of history of the chimney, when it was venting free gas. However, the presence of free gas beneath this chimney is probably why the water entering the chimney is already saturated with methane and the process of hydrate formation in the chimney continues today.

Original language	English
Article number	1250619
Number of pages	24
Journal	Frontiers in Earth Science
Volume	11
DOIs	https://doi.org/10.3389/feart.2023.1250619
Publication status	Published - 18 Oct 2023

Bibliographical note

Funding:
The MAK-1M side-scan sonar and profiler data were acquired during Leg 3 of Training Through Research Cruise 16 (2006) of the Professor Logachev, funded by the HERMES EU Integrated Project and STATOIL (co-chiefs M. Ivanov and GK. GW). The VICKING cruise was also supported by the HERMES project, funded by the European Commission’s Framework Six Programme, under the priority Sustainable Development, Global Change and Ecosystems, EC Contract No. GOCE-CT-2005-511234.

Keywords

dissolved methane
gas chimneys
chemosynthesis-based communities
seeps
Norwegian margin
pockmarks
authigenic carbonates
gas hydrate

Access to Document

10.3389/feart.2023.1250619Licence: Creative Commons: Attribution (CC BY)

DupréS2023MethaneFinal published version, 9.62 MBLicence: Creative Commons: Attribution (CC BY)

Cite this

@article{76b1216b1157464e827700792e5576d9,

title = "Methane-flow system within the Nyegga pockmark field, offshore mid-Norway",

abstract = "We investigated fluid seepage within the Nyegga pockmark field (600–900 m water depths) off mid-Norway from Remotely Operated Vehicle dives at the so-called CNE sites (CNE01 to CNE17). The seafloor morphology of some of these features corresponds to pockmarks and adjacent ridges, with the latter being the focus of present seepage activity. These structures are underlain by chimneys above a gas-charged zone with, in some cases, a substantial body of hydrate-invaded sediment (down to 1.3 s in two-way travel time at CNE03). Present-day methane-rich fluid seepage through the seabed is indicated by chemosynthetic fauna, in particular Siboglinidae polychaetes (Oligobrachia haakonmobiensis webbi and Sclerolinum contortum), microbial mats and associated Rissoidae gastropod (Alvania sp.) grazers, and confirmed by measured in situ bottom-water methane anomalies, up to 2,130 nL/L. No free-gas bubble emissions were observed or acoustically identified. The presence of authigenic carbonates reveals past seepage with very low δ13C values (down to −58‰) indicating that the major source of carbon was methane carried by the venting fluids. The ages of major periods of methane venting are provided by vesicomyid bivalve shells (Isorropodon nyeggaensis) present in two sedimentary layers, 14,930 and 15,500 14C yr BP (ca. 17,238 and 17,952 cal yr BP), respectively, corresponding to the time of Melt Water Pulse IA. The seafloor morphology and pattern of seepage -chemosynthetic fauna and microbial mat distribution and dissolved methane concentration-are remarkably heterogeneous. Pore-water chemistry profiles in a gravity core taken only 40 m from major seepage sites indicate no seepage and anaerobic methane oxidation at a sub-bottom depth of about 2 m. Present-day seepage from the studied pockmark-chimney fluid-flow system charged with gas hydrate is dominated by the advection of methane solution in pore water. Some of this methane could result from the dissolution of hydrate in the chimney, most of which would have formed during an earlier period (post-LGM times) of history of the chimney, when it was venting free gas. However, the presence of free gas beneath this chimney is probably why the water entering the chimney is already saturated with methane and the process of hydrate formation in the chimney continues today.",

keywords = "dissolved methane, gas chimneys, chemosynthesis-based communities, seeps, Norwegian margin, pockmarks, authigenic carbonates, gas hydrate",

author = "St{\'e}phanie Dupr{\'e} and Jean-Paul Foucher and Catherine Pierre and Carole Decker and Graham Westbrook and Stephan Ker and Karine Olu and Jean-Pierre Donval and Jean-Luc Charlou and Marie-Madeleine Blanc-Valleron and Herv{\'e} Nouz{\'e}",

note = "Funding: The MAK-1M side-scan sonar and profiler data were acquired during Leg 3 of Training Through Research Cruise 16 (2006) of the Professor Logachev, funded by the HERMES EU Integrated Project and STATOIL (co-chiefs M. Ivanov and GK. GW). The VICKING cruise was also supported by the HERMES project, funded by the European Commission{\textquoteright}s Framework Six Programme, under the priority Sustainable Development, Global Change and Ecosystems, EC Contract No. GOCE-CT-2005-511234.",

year = "2023",

month = oct,

day = "18",

doi = "10.3389/feart.2023.1250619",

language = "English",

volume = "11",

journal = "Frontiers in Earth Science",

issn = "2296-6463",

publisher = "Frontiers",

}

TY - JOUR

T1 - Methane-flow system within the Nyegga pockmark field, offshore mid-Norway

AU - Dupré, Stéphanie

AU - Foucher, Jean-Paul

AU - Pierre, Catherine

AU - Decker, Carole

AU - Westbrook, Graham

AU - Ker, Stephan

AU - Olu, Karine

AU - Donval, Jean-Pierre

AU - Charlou, Jean-Luc

AU - Blanc-Valleron, Marie-Madeleine

AU - Nouzé, Hervé

N1 - Funding: The MAK-1M side-scan sonar and profiler data were acquired during Leg 3 of Training Through Research Cruise 16 (2006) of the Professor Logachev, funded by the HERMES EU Integrated Project and STATOIL (co-chiefs M. Ivanov and GK. GW). The VICKING cruise was also supported by the HERMES project, funded by the European Commission’s Framework Six Programme, under the priority Sustainable Development, Global Change and Ecosystems, EC Contract No. GOCE-CT-2005-511234.

PY - 2023/10/18

Y1 - 2023/10/18

N2 - We investigated fluid seepage within the Nyegga pockmark field (600–900 m water depths) off mid-Norway from Remotely Operated Vehicle dives at the so-called CNE sites (CNE01 to CNE17). The seafloor morphology of some of these features corresponds to pockmarks and adjacent ridges, with the latter being the focus of present seepage activity. These structures are underlain by chimneys above a gas-charged zone with, in some cases, a substantial body of hydrate-invaded sediment (down to 1.3 s in two-way travel time at CNE03). Present-day methane-rich fluid seepage through the seabed is indicated by chemosynthetic fauna, in particular Siboglinidae polychaetes (Oligobrachia haakonmobiensis webbi and Sclerolinum contortum), microbial mats and associated Rissoidae gastropod (Alvania sp.) grazers, and confirmed by measured in situ bottom-water methane anomalies, up to 2,130 nL/L. No free-gas bubble emissions were observed or acoustically identified. The presence of authigenic carbonates reveals past seepage with very low δ13C values (down to −58‰) indicating that the major source of carbon was methane carried by the venting fluids. The ages of major periods of methane venting are provided by vesicomyid bivalve shells (Isorropodon nyeggaensis) present in two sedimentary layers, 14,930 and 15,500 14C yr BP (ca. 17,238 and 17,952 cal yr BP), respectively, corresponding to the time of Melt Water Pulse IA. The seafloor morphology and pattern of seepage -chemosynthetic fauna and microbial mat distribution and dissolved methane concentration-are remarkably heterogeneous. Pore-water chemistry profiles in a gravity core taken only 40 m from major seepage sites indicate no seepage and anaerobic methane oxidation at a sub-bottom depth of about 2 m. Present-day seepage from the studied pockmark-chimney fluid-flow system charged with gas hydrate is dominated by the advection of methane solution in pore water. Some of this methane could result from the dissolution of hydrate in the chimney, most of which would have formed during an earlier period (post-LGM times) of history of the chimney, when it was venting free gas. However, the presence of free gas beneath this chimney is probably why the water entering the chimney is already saturated with methane and the process of hydrate formation in the chimney continues today.

AB - We investigated fluid seepage within the Nyegga pockmark field (600–900 m water depths) off mid-Norway from Remotely Operated Vehicle dives at the so-called CNE sites (CNE01 to CNE17). The seafloor morphology of some of these features corresponds to pockmarks and adjacent ridges, with the latter being the focus of present seepage activity. These structures are underlain by chimneys above a gas-charged zone with, in some cases, a substantial body of hydrate-invaded sediment (down to 1.3 s in two-way travel time at CNE03). Present-day methane-rich fluid seepage through the seabed is indicated by chemosynthetic fauna, in particular Siboglinidae polychaetes (Oligobrachia haakonmobiensis webbi and Sclerolinum contortum), microbial mats and associated Rissoidae gastropod (Alvania sp.) grazers, and confirmed by measured in situ bottom-water methane anomalies, up to 2,130 nL/L. No free-gas bubble emissions were observed or acoustically identified. The presence of authigenic carbonates reveals past seepage with very low δ13C values (down to −58‰) indicating that the major source of carbon was methane carried by the venting fluids. The ages of major periods of methane venting are provided by vesicomyid bivalve shells (Isorropodon nyeggaensis) present in two sedimentary layers, 14,930 and 15,500 14C yr BP (ca. 17,238 and 17,952 cal yr BP), respectively, corresponding to the time of Melt Water Pulse IA. The seafloor morphology and pattern of seepage -chemosynthetic fauna and microbial mat distribution and dissolved methane concentration-are remarkably heterogeneous. Pore-water chemistry profiles in a gravity core taken only 40 m from major seepage sites indicate no seepage and anaerobic methane oxidation at a sub-bottom depth of about 2 m. Present-day seepage from the studied pockmark-chimney fluid-flow system charged with gas hydrate is dominated by the advection of methane solution in pore water. Some of this methane could result from the dissolution of hydrate in the chimney, most of which would have formed during an earlier period (post-LGM times) of history of the chimney, when it was venting free gas. However, the presence of free gas beneath this chimney is probably why the water entering the chimney is already saturated with methane and the process of hydrate formation in the chimney continues today.

KW - dissolved methane

KW - gas chimneys

KW - chemosynthesis-based communities

KW - seeps

KW - Norwegian margin

KW - pockmarks

KW - authigenic carbonates

KW - gas hydrate

U2 - 10.3389/feart.2023.1250619

DO - 10.3389/feart.2023.1250619

M3 - Article

SN - 2296-6463

VL - 11

JO - Frontiers in Earth Science

JF - Frontiers in Earth Science

M1 - 1250619

ER -

Methane-flow system within the Nyegga pockmark field, offshore mid-Norway

Abstract

Bibliographical note

Keywords

Access to Document

Fingerprint

Cite this