Predicting seal risk and charge capacity using chimney processing: Three Gulf of Mexico case histories

Walraven, David; Aminzadeh, Fred; Connolly, David

doi:10.1190/1.1851282

Cited by 6 publications

(4 citation statements)

References 4 publications

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“…Recent works by Ligtenberg and Thomsen (2003), Heggland (2005), Ligtenberg (2005), Walraven et al (2005a), and Roberts et al (2006) showed that 3-D seismic data are highly successful at detecting hydrocarbon migration pathways to or from a reservoir as well as possible expulsion sites and as such can be used to investigate the fluid transport properties of faults. Results of up-fault leakage will most likely affect the bulk proprieties of a rock body (Judd et al, 1992) in the fault zone or within adjacent discharge sites; it will then produce anomalies such as acoustic turbidity zones capturing gas chimneys, shallow seismic anomalies, and bright spots related to gas pockets (Kaluza and Doyle, 1996;Heggland, 2002;Aminzadeh et al, 2004;Walraven et al, 2005b;Cartwright et al, 2007;Halliday et al, 2008).…”

Section: Up-fault Remigration Indications From 3-d Seismic Datamentioning

confidence: 98%

Evaluating hydrocarbon trap integrity during fault reactivation using geomechanical three-dimensional modeling: An example from the Timor Sea, Australia

Langhi¹,

Zhang²,

Gartrell³

et al. 2010

Bulletin

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A B S T R A C TThree-dimensional (3-D) coupled deformation and fluid-flow numerical modeling are used to simulate the response of a relatively complex set of trap-bounding faults to extensional reactivation and to investigate hydrocarbon preservation risk for structural traps in the offshore Bonaparte Basin (Laminaria High, the Timor Sea, Australian North West Shelf ).The model results show that the distributions of shear strain and dilation as well as fluid flux are heterogeneous along fault planes inferring lateral variability of fault seal effectiveness. The distribution of high shear strain is seen as the main control on structural permeability and is primarily influenced by the structural architecture. Prereactivation fault size and distribution within the modeled fault population as well as fault corrugations driven by growth processes represent key elements driving the partitioning of strain and up-fault fluid flow. These factors are critical in determining oil preservation during the late reactivation phase on the Laminaria High.Testing of the model against leakage indicators defined on 3-D seismic data correlates with the numerical prediction of fault seal effectiveness and explains the complex distribution of paleo-and preserved oil columns in the study area.Laurent received an M.Sc. degree (2000) and a Ph.D. (2006) in geology from the University of Lausanne, Switzerland. After a year as a researcher at the University of Western Australia, he worked as an exploration geologist on west African basins. In 2006, he joined CSIRO Petroleum focusing on trap integrity prediction, visualization of migration pathways, and seismic attribute analysis.

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Section: Up-fault Remigration Indications From 3-d Seismic Datamentioning

confidence: 98%

Evaluating hydrocarbon trap integrity during fault reactivation using geomechanical three-dimensional modeling: An example from the Timor Sea, Australia

Langhi¹,

Zhang²,

Gartrell³

et al. 2010

Bulletin

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“…In petroliferous basins, gas chimneys provide clues for a better understanding of spatial and temporal linkages between various storeys of the petroleum system (Meldahl et al ., ; Løseth et al ., ). As summarized by Ligtenberg (), they can provide information as to the type of fluid activity in source rocks (Ligtenberg & Thomsen, ), top‐seal integrity analysis (Heggland, ; Walraven et al ., ; Cartwright et al ., ), and whether the potential target is charged or leaking (Heggland et al ., ).…”

Section: Introductionmentioning

confidence: 99%

Interpretation of a gas chimney in the Polish Carpathian Foredeep based on integrated seismic and geochemical data

et al. 2016

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Gas chimneys are common in offshore petroliferous basins, but little known on land where seismic columnar anomalies are often attributed as poor data quality or processing artefacts. This study utilizes high-quality 3D seismic data to document a seismic columnar anomaly penetrating through the Miocene heterolithic submarine fan-deltaic infill of the Carpathian Foredeep. The interpreted gas chimney exhibits vertically clustered velocity push-down features throughout the attenuated amplitude column accompanied by gas shows in well tests, has its root in gas-bearing Palaeozoic interval and culminates in an anomalous geochemical gas record at soil level. The chimney system, ca 2 km in height and 500-m wide, begins above the flank of a rotational bedrock fault-block and extends vertically along a fault-controlled conduit. At shallower levels, it passes upwards into amplitude wipeout zones that spread laterally around and partly across thin, gas-charged reservoirs showing bright spots associated with an AVO response. At shallow levels, gas pathways through muddy slope and deltaic clinoforms are not imaged in low-fold regions of the seismic volume. The surface geochemical anomalies, in contrast to the microbial methane signature of the Miocene succession, show significant enrichment in higher alkanes and alkenes with C 2 H 6 /C 3 H 8 ratios indicative of a deep-sourced, thermogenic gas or gas condensate. These anomalies form a semi-enclosed halo around the chimney. Despite the juxtaposition of biogenic and thermogenic methane, the chimney structure imaged on seismic data supports a causal link of gases derived from Palaeozoic source rocks ascending to the surface.

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“…Leakage from potential reservoirs, which may provide better insight in the lateral and top seal quality (Walraven et al , 2004).…”

Section: Introductionmentioning

confidence: 99%

“…Gas chimneys and fluids migrating along faults and reaching potential reservoir formations, thereby providing information about whether a prospect is charged or not (Heggland et al , 2000, 2001). Leakage from potential reservoirs, which may provide better insight in the lateral and top seal quality (Walraven et al , 2004). Leakage from these potential reservoirs to shallower levels and charging shallow sands, thus indicating the presence of shallow gas drilling hazards (e.g.…”

Section: Introductionmentioning

confidence: 99%

Detection of fluid migration pathways in seismic data: implications for fault seal analysis

Ligtenberg¹

2005

Basin Research

157

105

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A new and efficient method for fault seal analysis using seismic data is presented. It uses multiple seismic attributes and neural networks to enhance fluid migration pathways, including subtle features that are not detectable using single attributes only. The method may be used as a first estimate of fault seal or to calibrate results from other techniques. The results provide information about which faults and fault segments are sealing or leaking. Fluid flow along individual faults appears to be focused along zones of weakness, and fault seal research should thus be focused on finding such weak locations within fault zones, a task that is best done using three‐dimensional (3D) seismic data. Under certain conditions, it is suggested that fluids migrate along fault planes by a diapiric fluid flow mechanism. The results assist in calibrating the bulk hydraulic properties of faults and rock formations and can be used in basin modelling.

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Predicting seal risk and charge capacity using chimney processing: Three Gulf of Mexico case histories

Cited by 6 publications

References 4 publications

Evaluating hydrocarbon trap integrity during fault reactivation using geomechanical three-dimensional modeling: An example from the Timor Sea, Australia

Evaluating hydrocarbon trap integrity during fault reactivation using geomechanical three-dimensional modeling: An example from the Timor Sea, Australia

Interpretation of a gas chimney in the Polish Carpathian Foredeep based on integrated seismic and geochemical data

Detection of fluid migration pathways in seismic data: implications for fault seal analysis

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