Sonar gas flux estimation by bubble insonification: application to methane bubble flux from seep areas in the outer Laptev Sea

Leifer, Ira; Chernykh, Denis; Shakhova, Natalia; Semiletov, I. P.

doi:10.5194/tc-11-1333-2017

Cited by 36 publications

(50 citation statements)

References 58 publications

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“…The volumetric gas flux and methane mass flux estimated in this research are consistently lower than flux reported in previously published studies (Shakhova et al, 2010;Weber et al, 2014;Leifer et al, 2017). This is not surprising as both our estimates of volumetric gas flux and subsequent estimates of methane flux represent lower bounds of the true regional flux.…”

Section: Discussionsupporting

confidence: 66%

A wideband acoustic method for direct assessment of bubble-mediated methane flux

Weidner

Weber

Mayer

et al. 2019

Continental Shelf Research

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Section: Discussionsupporting

confidence: 66%

A wideband acoustic method for direct assessment of bubble-mediated methane flux

Weidner

Weber

Mayer

et al. 2019

Continental Shelf Research

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“…Estimates of global seep emissions are based on a very limited number of measurements. Fluxes for individual marine seep vents have been reported for the Gulf of Mexico [33], offshore Norway [34,35], the North Sea [36], offshore Svalbard in the Norwegian Arctic [37], the arctic Laptev Sea [38], and numerous vents in the COP seep field [39].…”

Section: Definition Of Seepagementioning

confidence: 99%

“…Many authors have noted a relationship between seepage and geologic structures [1,2,97,107,108], including faults, diapirs, outcrops, and slumps. Near-seabed geologic structures such as authigenic carbonates [109] and low permeability sediment layers like clay [110] and ancient river valleys [38] also provide spatial control. These structures relate to low permeability migration pathways and/or allow for hydrocarbon accumulation.…”

Section: Spatial Geological Control On Seepagementioning

confidence: 99%

“…Although studies long have investigated geological controls on the spatial occurrence of seepage [96], few have investigated seep strength with respect to geological controls; e.g., Leifer et al [102] showed fine-scale (<100 m) spatial control of emissions by geological structures (Figure 12), and Leifer et al [38] showed quantitative multibeam sonar emission data that were proposed related to near-surface geological controls on a meter to 10 m scales in both the COP seep field and the Arctic. Bradley et al [53] showed geological controls on trends in the spatial seepage emission distribution-proposed related to vent activation and deactivation based on overpressure and permeability.…”

Section: Geological and Other Controls On Seepagementioning

confidence: 99%

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A Synthesis Review of Emissions and Fates for the Coal Oil Point Marine Hydrocarbon Seep Field and California Marine Seepage

Leifer

2019

Geofluids

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Anthropogenic oil in the ocean is of great concern due to its potential immediate and long-term impacts on the ecosystem, economy, and society, leading to intense societal efforts to mitigate and reduce inputs. Sources of oil in the ocean (in the order of importance) are natural marine seepage, run-off from anthropogenic sources, and oil spills, yet uncertainty and variability in these budgets are large, particularly for natural seepage, which exhibits large spatial and temporal heterogeneity on local to regional scales. When source inputs are comparable, discriminating impacts is complicated, because petroleum is both a bioavailable, chemosynthetic energy source to the marine ecosystem and a potential toxic stressor depending on concentration, composition, and period of time. This synthesis review investigates the phenomena underlying this complexity and identifies knowledge gaps. Its focus is on the Coal Oil Point (COP) seep field, arguably the best-studied example, of strong natural marine hydrocarbon seepage, located in the nearshore, shallow waters of the Northern Santa Barbara Channel, Southern California, where coastal processes complicate oceanography and meteorology. Many of our understandings of seep processes globally are based on insights learned from studies of the oil and gas emissions from the COP seep field. As one of the largest seep fields in the world, its impacts spread far as oil drifts on the sea surface and subsurface, yet much remains unknown of its impacts.

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“…The Ob and Yenisei Rivers transport significant sediment, underlying the shallowness of the Kara Sea, with extensive proven and proposed petroleum hydrocarbon reservoirs underlying the east and southeast Kara Sea (Rekacewicz, 2005). Given the Kara Sea's shallowness, CH4 seep seabed bubbles can mostly transfer their gas directly to the atmosphere (Leifer et al, 2017;Leifer and Patro, 2002) and indirectly from wind mixing (Wanninkhof and McGillis, 1999), and also from storm sparging (Boitsov et al, 2012;Shakhova et al, 2013), which in the Arctic can extend to 100-200 m depth, i.e., most of the Kara Sea. Figure S2.…”

Section: S3 Detailed Currents and Bathymetrymentioning

confidence: 99%

Supplementary material to "Satellite ice extent, sea surface temperature, and atmospheric methane trends in the Barents and Kara Seas"

Leifer¹,

Chen²,

McClimans³

et al. 2018

Preprint

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Supplementary Material S1. Review of Airborne Arctic Methane measurements CH4 concentration profiles over the Arctic Ocean were measured on five flights during the HIAPER Pole-to-Pole Observations (HIPPO) campaign (Kort et al., 2012; Wofsy, 2011) and produced evidence of sea surface CH4 emissions from the northern Chukchi and Beaufort Seas in most profiles, up to 82°N. Enhanced concentrations near the sea surface were common over fractured floating ice in sample profiles collected on 2 Nov.

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Sonar gas flux estimation by bubble insonification: application to methane bubble flux from seep areas in the outer Laptev Sea

Cited by 36 publications

References 58 publications

A wideband acoustic method for direct assessment of bubble-mediated methane flux

A wideband acoustic method for direct assessment of bubble-mediated methane flux

A Synthesis Review of Emissions and Fates for the Coal Oil Point Marine Hydrocarbon Seep Field and California Marine Seepage

Supplementary material to "Satellite ice extent, sea surface temperature, and atmospheric methane trends in the Barents and Kara Seas"

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Sonar gas flux estimation by bubble insonification: application to methane bubble flux from seep areas in the outer Laptev Sea

Cited by 36 publications

References 58 publications

A wideband acoustic method for direct assessment of bubble-mediated methane flux

A wideband acoustic method for direct assessment of bubble-mediated methane flux

A Synthesis Review of Emissions and Fates for the Coal Oil Point Marine Hydrocarbon Seep Field and California Marine Seepage

Supplementary material to &quot;Satellite ice extent, sea surface temperature, and atmospheric methane trends in the Barents and Kara Seas&quot;

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Supplementary material to "Satellite ice extent, sea surface temperature, and atmospheric methane trends in the Barents and Kara Seas"