Gas hydrate dissociation linked to contemporary ocean warming in the southern hemisphere

Ketzer, Marcelo; Praeg, Daniel; Rodrigues, Luiz Frederico; Augustin, Adolpho Herbert; Pivel, M A; Rahmati-Abkenar, Mahboubeh; Miller, Dennis J.; Viana, Adriano R.; Cupertino, José

doi:10.1038/s41467-020-17289-z

Cited by 69 publications

(53 citation statements)

References 67 publications

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“…When it exists, the BSR often decreases as the seabed shallows until it intersects with the seabed, where it is known as the landward limit of gas hydrate stability zone (LLGHSZ) representing the shallowest water depth of GHSZ. Due to limited methane supply and the anaerobic oxidation of methane (AOM) at shallow depth, both BSR and LLGHSZ are rarely visible in the vicinity of the theoretical LLGHSZ in seismic data in many gas hydrate occurrence areas [4,35,[48][49][50]. In areas without BSR development, it is difficult to recognize the GHSZ which may hinder judging whether the methane source for the seabed methane seepage is related with the gas hydrate systems or not.…”

Section: Gas Hydrate Stability Zone (Ghsz)mentioning

confidence: 99%

“…Seabed methane seepage is often characterized by seabed manifestations such as methane flares, pockmarks, carbonate crusts on mounds or pavements, coral reefs, mud volcanoes, hydrate pingoes, and chemosynthetic biological communities [1,4,12,52,53]. The size and density of these seabed manifestations reflect the volume of methane transferred from geosphere to hydrosphere or even the atmosphere, whose presence also indicates the existence of underlying hydrocarbon reservoirs or gas hydrate systems [1,53].…”

Section: Characterization Of Seabed Methane Seepage Manifestationsmentioning

confidence: 99%

“…In recent years, seabed methane seepage has gained attention from all over the world as an important source of greenhouse gas emission which may affect climate change or even global warming (Figure 1) [1][2][3][4]. Seabed methane seepage features, also termed as "cold seeps," refer to the seeping or venting features of fluids at the seabed.…”

Section: Introductionmentioning

confidence: 99%

“…(b) Global distribution of deep-water reef-forming corals (from Roberts et al [8]). 2 Geofluids seabed temperature change (also called ocean warming), seabed bottom currents, salinity change of seawater, and ice sheet fluctuations, all of which can change the pressure and temperature conditions of gas hydrate stability, therefore causing gas hydrate dissociation and probably subsequent methane seepage at the seabed [3,4,[11][12][13][14][15]. For example, NASA scientists observed millions of seabed methane seeps in the Arctic region and it was proposed that the postglacial climate warming and deglaciation caused the dissociation of gas hydrates, therefore leading to the seabed methane release [16,17].…”

Section: Introductionmentioning

confidence: 99%

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A Geophysical Review of the Seabed Methane Seepage Features and Their Relationship with Gas Hydrate Systems

Yang

Zheng

et al. 2021

Geofluids

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Seabed methane seepage has gained attention from all over the world in recent years as an important source of greenhouse gas emission, and gas hydrates are also regarded as a key factor affecting climate change or even global warming due to their shallow burial and poor stability. However, the relationship between seabed methane seepage and gas hydrate systems is not clear although they often coexist in continental margins. It is of significance to clarify their relationship and better understand the contribution of gas hydrate systems or the deeper hydrocarbon reservoirs for methane flux leaking to the seawater or even the atmosphere by natural seepages at the seabed. In this paper, a geophysical examination of the global seabed methane seepage events has been conducted, and nearby gas hydrate stability zone and relevant fluid migration pathways have been interpreted or modelled using seismic data, multibeam data, or underwater photos. Results show that seabed methane seepage sites are often manifested as methane flares, pockmarks, deep-water corals, authigenic carbonates, and gas hydrate pingoes at the seabed, most of which are closely related to vertical fluid migration structures like faults, gas chimneys, mud volcanoes, and unconformity surfaces or are located in the landward limit of gas hydrate stability zone (LLGHSZ) where hydrate dissociation may have released a great volume of methane. Based on a comprehensive analysis of these features, three major types of seabed methane seepage are classified according to their spatial relationship with the location of LLGHSZ, deeper than the LLGHSZ (A), around the LLGHSZ (B), and shallower than LLGHSZ (C). These three seabed methane seepage types can be further divided into five subtypes considering whether the gas source of seabed methane seepage is from the gas hydrate systems or not. We propose subtype B2 represents the most important seabed methane seepage type due to the high density of seepage sites and large volume of released methane from massive focused vigorous methane seepage sites around the LLGHSZ. Based on the classification result of this research, more measures should be taken for subtype B2 seabed methane seepage to predict or even prevent ocean warming or climate change.

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Section: Gas Hydrate Stability Zone (Ghsz)mentioning

confidence: 99%

Section: Characterization Of Seabed Methane Seepage Manifestationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Geophysical Review of the Seabed Methane Seepage Features and Their Relationship with Gas Hydrate Systems

Yang

Zheng

et al. 2021

Geofluids

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“…Naturally occurring methane hydrate is abundant in oceanic settings, but changes in pressure and temperature (P-T) cause it to dissociate, potentially allowing methane to escape to the atmosphere and amplify climatic change (Ruppel and Kessler, 2017) or oxidize in seawater and contribute to ocean acidification (Biastoch et al, 2011). Seaward shifts of the updip feather edge of marine methane hydrate resulting in methane venting to the ocean have been documented due to contemporary warming of bottom waters (Skarke et al, 2014;Ketzer et al, 2020), but this has not been demonstrated for past climate change on canyon-incised margins. There are >5800 submarine canyons, with a total length of 254,000 km, on Earth (Harris and Whiteway, 2011), and methane emissions and hydrate have been detected in canyons (e.g., Barkley Canyon, offshore British Columbia, Canada: Thomsen et al, 2012; Hudson Canyon, offshore northeastern United States: Weinstein et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Climatically driven instability of marine methane hydrate along a canyon-incised continental margin

Davies

Maqueda

et al. 2021

Geology

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Establishing how past climate change affected the stability of marine methane hydrate is important for our understanding of the impact of a future warmer world. As oceans shallow toward continental margins, the base of the hydrate stability zone also shallows, and this delineates the feather edge of marine methane hydrate. It is in these rarely documented settings that the base of the hydrate stability zone intersects the seabed and hydrate can crop out where it is close to being unstable and most susceptible to dissociation due to ocean warming. We show evidence for a seismically defined outcrop zone intersecting canyons on a canyon-incised margin offshore of Mauritania. We propose that climatic, and hence ocean, warming since the Last Glacial Maximum as well as lateral canyon migration, cutting, and filling caused multiple shifts of the hydrate stability field, and therefore hydrate instability and likely methane release into the ocean. This is particularly significant because the outcrop zone is longer on canyon-incised margins than on less bathymetrically complex submarine slopes. We propose considerably more hydrate will dissociate in these settings during future ocean warming, releasing methane into the world’s oceans.

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Calcium carbonate dissolution triggered by high productivity during the last glacial-interglacial interval at the deep western South Atlantic

Suárez-Ibarra

Frozza

Petró

et al. 2021

Preprint

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Studies reconstructing surface paleoproductivity and benthic environmental conditions allow us to measure the effectiveness of the biological pump, an important mechanism in the global climate system. In order to assess surface productivity changes and their effect on the seafloor, we studied the sediment core SAT-048A, spanning 43-5 ka, recovered from the continental slope (1,542 m water depth) of the southernmost Brazilian continental margin, deep western South Atlantic. We assessed the sea surface productivity, the organic matter flux to the seafloor, and calcite dissolution effects, based on micropaleontological (benthic and planktonic foraminifers, ostracods), geochemical (benthic δ 13 C isotopes), and sedimentological data (carbonate and bulk sand content). Superimposed on the induced changes related to the last glacial-interglacial transition, the reconstruction indicates a significant and positive correlation between the paleoproductivity proxies and the summer insolation. From the reconstructed data, it was possible to identify high (low) surface productivity, high (low) organic matter flux to the seafloor, and high (low) dissolution rates of planktonic Foraminifera tests during the glacial (postglacial). Furthermore, within the glacial, enhanced productivity was associated with higher insolation values, explained by increased northeasterly summer winds that promoted meandering and upwelling of the nutrient-rich South Atlantic Central Water. Statistical analyses support the idea that productivity is the main cause for seafloor calcium carbonate dissolution, as opposed to changes in the Atlantic Meridional Overturning Circulation (at least for the 25-4 ka period). Further efforts must be invested in the comprehension and quantification of the total organic matter and biogenic carbonate burial during time intervals with an enhanced biological pump, aiming to better understand their individual roles.

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Gas hydrate dissociation linked to contemporary ocean warming in the southern hemisphere

Cited by 69 publications

References 67 publications

A Geophysical Review of the Seabed Methane Seepage Features and Their Relationship with Gas Hydrate Systems

A Geophysical Review of the Seabed Methane Seepage Features and Their Relationship with Gas Hydrate Systems

Climatically driven instability of marine methane hydrate along a canyon-incised continental margin

Calcium carbonate dissolution triggered by high productivity during the last glacial-interglacial interval at the deep western South Atlantic

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