Insights into the permeability of polygonal faults from their intersection geometries with Linear Chimneys: a case study from the Lower Congo Basin

Ho, Sutieng; Carruthers, Daniel; Imbert, Patrice

doi:10.4267/2042/58718

Cited by 15 publications

(17 citation statements)

References 30 publications

(32 reference statements)

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“…2b). These intervals are deformed by polygonal faulting, which conforms to two distinct tiers, named here as Tier-1 and Tier-2 (Ho et al, 2012a(Ho et al, , 2016(Ho et al, , 2018Ho, 2013). The deepest Tier-1 ranges from 70-130 m thick and contains the Late Miocene units, whilst the shallower Tier-2 contains the Pliocene units and has a maximum thickness of ca.…”

Section: Miocene To Quaternary Stratigraphy and Elementsmentioning

confidence: 99%

Part 2 - authors reply to Review 1 of the Discussion Paper titled “Formation of linear planform chimneys controlled by preferential hydrocarbon leakage and anisotropic stresses in faulted ﬁne-grained sediments, Offshore Angola” by Ho et al.

Ho¹

2018

Preprint

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A new type of gas chimney exhibiting an unconventional linear planform is found. These chimneys are termed "Linear Chimneys", which have been observed in 3-D seismic data offshore of Angola. Linear Chimneys occur parallel to adjacent faults, often within preferentially oriented tier-bound fault networks of diagenetic origin (also known as anisotropic polygonal faults, PFs), in salt-deformational domains. These anisotropic PFs are parallel to salt-tectonicrelated structures, indicating their submission to horizontal stress perturbations generated by the latter. Only in areas with these anisotropic PF arrangements do chimneys and their associated gas-related structures, such as methane-derived authigenic carbonates and pockmarks, have linear planforms. In areas with the classic "isotropic" polygonal fault arrangements, the stress state is isotropic, and gas expulsion structures of the same range of sizes exhibit circular geometry. These events indicate that chimney's linear planform is heavily influenced by stress anisotropy around faults. The initiation of polygonal faulting occurred 40 to 80 m below the present day seafloor and predates Linear Chimney formation. The majority of Linear Chimneys nucleated in the lower part of the PF tier below the impermeable portion of fault planes and a regional impermeable barrier within the PF tier. The existence of polygonal fault-bound traps in the lower part of the PF tier is evidenced by PF cells filled with gas. These PF gas traps restricted the leakage points of overpressured gas-charged fluids along the lower portion of PFs, hence controlling the nucleation sites of chimneys. Gas expulsion along the lower portion of PFs preconfigured the spatial organisation of chimneys. Anisotropic stress conditions surrounding tectonic and anisotropic polygonal faults coupled with the impermeability of PFs determined the directions of long-term gas migration and linear geometries of chimneys. Methane-related carbonates that precipitated above Linear Chimneys inherited the same linear planform geometry, and both structures record the timing of gas leakage and palaeostress state; thus, they can be used as a tool to reconstruct orientations of stress in sedimentary successions. This study demonstrates that overpressure hydrocarbon migration via hydrofracturing may be energetically more favourable than migration along pre-existing faults.

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Section: Miocene To Quaternary Stratigraphy and Elementsmentioning

confidence: 99%

Part 2 - authors reply to Review 1 of the Discussion Paper titled “Formation of linear planform chimneys controlled by preferential hydrocarbon leakage and anisotropic stresses in faulted ﬁne-grained sediments, Offshore Angola” by Ho et al.

Ho¹

2018

Preprint

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“…In addition, mineralized fluids intensify diagenesis in the fracture planes, rendering this interval all the more impermeable (Laurent et al, 2012). The detailed analysis of the geometric relationships between highimpedance seismic anomalies and polygonal fault pairs reveals that they can act as a seal during early stages of burial (Ho et al, 2016). In the Congo Basin, the Pliocene-present interval contains widespread fluid escape features, at seabed and in the subsurface, indicating past and ongoing bypass of the regional seal which is intensely affected by a major polygonal fault system (Gay et al, 2004).…”

Section: Organic Matter Preservation and Shallow Fluid Migrationmentioning

confidence: 99%

Geological fluid flow in sedimentary basins

Migeon

2017

Bull. Soc. géol. Fr.

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“…The morphology of structures formed during fluid leakage records the style and intensity of fluid expulsion and is thus useful for deciphering the fluid migration history (Roberts et al, 2006;Blouet et al, 2017;Imbert et al, 2017;Imbert and Ho, 2012;Ho et al, 2012bHo et al, , 2018. As 3-D seismic reflection data have played an increasingly important role in visualisation and identification of fluid flow features (Heggland, 1997), by conducting seismic analyses for vertical successions of fluid leakage expressions around faults, such as gas chimneys feeding pockmarks and seep carbonates, it is possible to unravel the timing and pathways of migrating fluids and the sealing efficiency of faults (Ligtenberg, 2005;Plaza-Faverola et al, 2012;Ho et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Recent studies from the upper slope of the Lower Congo Basin have revealed the existence of a new type of chimney (Ho et al, 2016;Ho, 2013). Chimneys are usually circular in planform.…”

Section: Introductionmentioning

confidence: 99%

Formation of linear planform chimneys controlled by preferential hydrocarbon leakage and anisotropic stresses in faulted fine-grained sediments, offshore Angola

Hovland

Blouet

et al. 2018

Solid Earth

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Abstract. A new type of gas chimney exhibiting an unconventional linear planform is found. These chimneys are termed Linear Chimneys, which have been observed in 3-D seismic data offshore of Angola. Linear Chimneys occur parallel to adjacent faults, often within preferentially oriented tier-bound fault networks of diagenetic origin (also known as anisotropic polygonal faults, PFs), in salt-deformational domains. These anisotropic PFs are parallel to salt-tectonic-related structures, indicating their submission to horizontal stress perturbations generated by the latter. Only in areas with these anisotropic PF arrangements do chimneys and their associated gas-related structures, such as methane-derived authigenic carbonates and pockmarks, have linear planforms. In areas with the classic isotropic polygonal fault arrangements, the stress state is isotropic, and gas expulsion structures of the same range of sizes exhibit circular geometry. These events indicate that chimney's linear planform is heavily influenced by stress anisotropy around faults. The initiation of polygonal faulting occurred 40 to 80 m below the present day seafloor and predates Linear Chimney formation. The majority of Linear Chimneys nucleated in the lower part of the PF tier below the impermeable portion of fault planes and a regional impermeable barrier within the PF tier. The existence of polygonal fault-bound traps in the lower part of the PF tier is evidenced by PF cells filled with gas. These PF gas traps restricted the leakage points of overpressured gas-charged fluids along the lower portion of PFs, hence controlling the nucleation sites of chimneys. Gas expulsion along the lower portion of PFs preconfigured the spatial organisation of chimneys. Anisotropic stress conditions surrounding tectonic and anisotropic polygonal faults coupled with the impermeability of PFs determined the directions of long-term gas migration and linear geometries of chimneys. Methane-related carbonates that precipitated above Linear Chimneys inherited the same linear planform geometry, and both structures record the timing of gas leakage and palaeo-stress state; thus, they can be used as a tool to reconstruct orientations of stress in sedimentary successions. This study demonstrates that overpressure hydrocarbon migration via hydrofracturing may be energetically more favourable than migration along pre-existing faults.

show abstract

Insights into the permeability of polygonal faults from their intersection geometries with Linear Chimneys: a case study from the Lower Congo Basin

Cited by 15 publications

References 30 publications

Part 2 - authors reply to Review 1 of the Discussion Paper titled “Formation of linear planform chimneys controlled by preferential hydrocarbon leakage and anisotropic stresses in faulted ﬁne-grained sediments, Offshore Angola” by Ho et al.

Part 2 - authors reply to Review 1 of the Discussion Paper titled “Formation of linear planform chimneys controlled by preferential hydrocarbon leakage and anisotropic stresses in faulted ﬁne-grained sediments, Offshore Angola” by Ho et al.

Geological fluid flow in sedimentary basins

Formation of linear planform chimneys controlled by preferential hydrocarbon leakage and anisotropic stresses in faulted fine-grained sediments, offshore Angola

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