Pore water geochemistry at two seismogenic areas in the Sea of Marmara

Ruffine, Livio; Germain, Yoan; Polonia, Alina; Prunelé, Alexis De; Croguennec, Claire; Donval, Jean-Pierre; Pitel-Roudaut, Mathilde; Ponzevera, Emmanuel; Caprais, Jean‐Claude; Brandily, Christophe; Grall, C.; Bollinger, Claire; Géli, Louis; Gasperini, Luca

doi:10.1002/2015gc005798

Cited by 20 publications

(17 citation statements)

References 98 publications

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“…Geochemistry, Geophysics, Geosystems 2.51 ± 0.007 mmol/L, respectively. The concentration of the SO 4 2À in ambient seawater was 29.52 ± 1.09 mmol/L, very similar to that of standard seawater (approximately 28 mmol/L, tested by Ruffine et al, 2015). The Raman signals of dissolved SO 4 2À and gaseous CH 4 were found in the spectra acquired by the RiP-Cs probe without filter and tip.…”

Section: 1029/2018gc007496supporting

confidence: 69%

In situ Raman Quantitative Detection of the Cold Seep Vents and Fluids in the Chemosynthetic Communities in the South China Sea

Zhang

Luan

et al. 2018

Geochem Geophys Geosyst

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Based on the previously developed deep-sea hybrid Raman insertion probe for cold seeps, the in situ detection of a cold seep vent and geochemistry analysis of fluids in chemosynthetic communities were conducted at the Formosa Ridge in the northern South China Sea. Three different methods were used to measure the components of the fluids erupting from the cold seep vent. The in situ Raman spectra of the cold seep fluids indicated the presence of gaseous CH 4 , C 3 H 8 , and H 2 S. The results indicate that the gases at this site are of biogenic origin; however, the presence of C 3 H 8 suggests that thermogenic methane should not be excluded. The conclusion is also supported by the results of gas chromatography and stable carbon isotope analysis. More significantly, we found that the concentration of SO 4 2À decreases with increasing depth, while the concentrations of CH 4 and S 8 increase in fluids in chemosynthetic communities, but without H 2 S. This finding indicates that the methane is oxidized by sulfate and that elemental sulfur is formed. This process usually occurs in marine sediments as the anaerobic oxidation of methane. Overall, the findings in this work provide a new insight into the geochemical analysis of cold seep fluids and in situ evidence of the oxidation of methane in the chemosynthetic communities near cold seeps.

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Section: 1029/2018gc007496supporting

confidence: 69%

In situ Raman Quantitative Detection of the Cold Seep Vents and Fluids in the Chemosynthetic Communities in the South China Sea

Zhang

Luan

et al. 2018

Geochem Geophys Geosyst

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“…Our uppermost pore-water sample was collected at 62 cmbsf. Such low values close to the sediment-water interface are often encountered at sites characterized by methane emissions or shallow gas hydrates (Chuang et al, 2013;Ruffine et al, 2015;Tryon et al, 2010;Wilson et al, 2014), and usually results from the anaerobic oxidation of methane (AOM) coupled with sulfate reduction near this interface. However, we have demonstrated in the previous section that the shallowest SMTZ is located at around 400 cmbsf, therefore quite far from the sediment-water interface.…”

Section: Unusual Location Of the Methane Source And The Consequence Omentioning

confidence: 99%

Evidence and age estimation of mass wasting at the distal lobe of the Congo deep-sea fan

Croguennec

Ruffine

Dennielou

et al. 2017

Deep Sea Research Part II: Topical Studies in Oceanography

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International audienceOn continental margins, sulfate reduction occurs within the sedimentary column. It is coupled with the degradation of organic matter and the anaerobic oxidation of methane. These processes may be significantly disturbed by sedimentary events, leading to transient state profiles for the involved chemical species. Yet, little is known about the impact of turbidity currents and mass wasting on the migration of chemical species and the redox reactions in which they are involved. Due to its connection to the River, the Congo deep-sea fan continuously receives huge amount of organic matter-rich sediments primarily transported by turbidity currents, which impact on the development of the associated ecosystems (Rabouille et al., 2016). Thus, it is well suited to better understand causal relationships between sedimentary events and fluid flow path, with consequences on the zonation of early diagenesis sequences. Here, we combined sedimentological observations with geochemical analyses of pore-water and sediment samples to explore how sedimentary instabilities affected the migration of methane and the distribution of organic matter within the sedimentary column. The results unveiled mass wasting processes affecting recent turbiditic and pelagic deposits, and are interpreted as being slides/ slumps and debrites. Two slides were responsible for the exhumation of an organic matter-rich sedimentary block of more than 5 m thick and the movement of a methane-rich sedimentary block, while turbidity currents enable the intercalation of sandy intervals within a pelagic clay layer. The youngest slide promoted the development of two Sulfate Methane Transition Zones (SMTZ), and may have possibly triggered a lateral migration of methane. Numerical simulation of the sulfate profile indicates that the youngest sedimentary event has occurred around a century ago. Our study emphasizes that turbidity currents and sedimentary instabilities can significantly affect the transport paths and the distribution of both methane and organic matter in the terminal lobe complex, with consequences on geochemical zonation of the sequential early diagenetic processes within the sedimentary column

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“…The recovered samples were the most propane-enriched hydrates ever collected (Bourry et al, 2009;Ruffine et al, 2012). The pore fluids were very diverse and complex in composition, reflecting mixing of fluids from different sources (Ruffine et al, 2015;Tryon et al, 2010;Zitter et al, 2008) as well as variations with time (Tryon et al, 2012). Such fluid emissions favored the development of microbial chemosynthetic communities (Ritt et al, 2010); especially those involved in the anaerobic oxidation of methane (AOM) and other heavier hydrocarbons.…”

Section: Introductionmentioning

confidence: 99%