How to evacuate 10 km3 of mud: saturate with gas and decrease the pressure!

Imbert, Patrice; Geiss, Bernard; Martín, Núria Fatjó de

doi:10.1007/s00367-014-0357-3

Cited by 13 publications

(7 citation statements)

References 38 publications

(52 reference statements)

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“…This can be due either to a quiescent phase of the MV activity when normal sedimentation was recorded or to very high sedimentation events, such as mass‐flows, that can drap MVs (Deville et al, ). The continuity of the seismic horizon separating the two mud masses is in favor of a normal sedimentation and does not seem related to any sediment instability present during the Post‐Absheron interval (Imbert et al, ). Normal faults flank the bowl‐shaped area from 1,500 to 2,000 m and show the motion toward the center of the bowl‐shaped geometry.…”

Section: Resultsmentioning

confidence: 99%

“…Methane was recently discovered in the Absheron field, and a giant active MV pierces the crest of the structure at the southwestern limit creating potential hazards for drilling operations (Contet & Unterseh, ). Previous studies on the Absheron anticline evidenced the presence of four mass transport deposits in the Post‐Absheron interval (Imbert et al, ). The most recent mass transport deposit covers the whole anticline with the exception of the MV location where it stumbles on the northern flank of the volcano.…”

Section: Regional Settingmentioning

confidence: 90%

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Evolution Model for the Absheron Mud Volcano: From In Situ Observations to Numerical Modeling

et al. 2019

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The morphology of mud volcanoes (MVs) has been extensively studied over the last few decades. Although recent research has begun to focus on deep processes and structures, little is known about mud generation mechanisms. This study aims to investigate the feeder system and formation of an active kilometer‐scale MV by relying on a 3‐D seismic survey and an in situ data set on the Absheron anticline (South Caspian Basin). Seismic data show a depleted area in the Anhydritic Surakhany Formation (ASF), whose mineralogical composition fits with surface mud. Well data show that the ASF is a succession of evaporitic beds and low‐temperature shales near its fracture pressure. Biostratigraphic analysis confirms a Pliocene origin for the mud, suggesting that the ASF may be the source. Numerical modeling of sedimentation coupled with laboratory test results and well sonic logs fairly reproduces the observed in situ overpressure trend. Two‐dimensional methane diffusion coupled with overpressure caused by rapid sedimentation highlights the superposition of critical fracturing conditions with methane‐saturated sediments at the base of the studied MV. The present study demonstrates the predominant role of fluid overpressure due to sedimentation and gas saturation in the formation of the Absheron MV, and this is shown to occur as follows: (1) methane migration through the thrust‐related faults reaching the ASF, accompanied by (2) lateral overpressure, caused by rapid sedimentation, diffusing along the ASF leading to (3) hydro‐fracturing of overpressured and methane‐saturated sediments resulting in an important decrease in overpressure, causing (4) gas exsolution and expansion triggering sediment remobilization.

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Section: Resultsmentioning

confidence: 99%

Section: Regional Settingmentioning

confidence: 90%

Evolution Model for the Absheron Mud Volcano: From In Situ Observations to Numerical Modeling

et al. 2019

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“…The combination of pre-existing gas saturation and a rapid pressure change is believed to explain most of the mud volcanism and diapirism phenomena worldwide (Imbert et al, 2014). In the Maiella area, pressure release after the unloading following the MES provoked hydrofracturing in limestones mounds, venting in correspondence with discrete features , as well as evaporite disruption.…”

Section: A C C E P T E D Accepted Manuscriptmentioning

confidence: 99%

Deep-seated hydrocarbons in the seep “Brecciated Limestones” of the Maiella area (Adriatic foreland basin): Evaporitic sealing and oil re-mobilization effects linked to the drawdown of the Messinian Salinity Crisis

Iadanza

Sampalmieri

Cipollari

2015

Marine and Petroleum Geology

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“…The presence of even modest amounts of methane in solution in the pore fluid could have had profound consequences and aid the process of dynamic liquefaction in the source units (c.f. Imbert et al (2014)). These essentially rapid overpressuring mechanisms may have had a role in taking the source region to the necessary state to achieve local liquefaction, but they would have been superimposed, in all likelihood, on a system that was already highly overpressured, possibly with a large, highly overpressured region developed within the entire presalt succession, such that only a minor trigger of a rapid event would be needed to exceed the necessary threshold.…”

Section: The Processes Of Remobilisationmentioning

confidence: 99%

The spatial, temporal and volumetric analysis of a large mud volcano province within the Eastern Mediterranean

Kirkham

Cartwright

Hermanrud

et al. 2017

Marine and Petroleum Geology

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This paper documents and describes through the use of 3D seismic data a prolific mud volcano province within the Eastern Mediterranean. As many as 386 mud volcanoes were mapped within the post-salt succession of the western slope of the Nile Cone, offshore Egypt, using high resolution 3D seismic data. The mud volcanoes within this field display significant geometrical variability in diameter (c. 550 m to c. 5660 m), height (c. 25m to c. 510 m) and volume (c. 0.1 km 3 to c. 3.3 km 3) and lie at depths ranging from c. > 6000 m subsea to c. 3100 m at the seafloor. A close spatial relationship between mud volcanoes and base-salt depressions and regions of anomalous thinning within the immediate pre-salt succession, combined with documented core samples taken from mud volcanoes within this region present a powerful argument for a pre-salt source of mud. 3D seismic interpretation and volumetric analysis of these mud volcanoes and their source region permit the definition and quantification of their depletion zones. A conceptual model for a dynamic liquefaction and sediment withdrawal process is proposed whereby mud is fed into a central conduit as the depletion zone propagates radially and episodically outwards resulting in a the formation of a concentric depletion zones. Prolonged mud volcanism within this region over the last ~5.3 Ma implies the potential for long lived pre-salt overpressure and continued mud volcanism following the catastrophic hydrodynamic impact of the Messinian Salinity Crisis. It is suggested that the scale of mud volcanism means that this region should be considered as among the largest mud volcano provinces in the world.

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How to evacuate 10 km3 of mud: saturate with gas and decrease the pressure!

Cited by 13 publications

References 38 publications

Evolution Model for the Absheron Mud Volcano: From In Situ Observations to Numerical Modeling

Evolution Model for the Absheron Mud Volcano: From In Situ Observations to Numerical Modeling

Deep-seated hydrocarbons in the seep “Brecciated Limestones” of the Maiella area (Adriatic foreland basin): Evaporitic sealing and oil re-mobilization effects linked to the drawdown of the Messinian Salinity Crisis

The spatial, temporal and volumetric analysis of a large mud volcano province within the Eastern Mediterranean

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