Large-scale 3D seismic attribute analysis framework based on double-layer Flood Fill

We analyzed a 1991 3D seismic data located offshore Florida and applied seismic attribute analysis to identify geological structures. Initially, the seismic data appears to have a high signal-to-noise-ratio, being of an older vintage of quality, and appears to reveal variable amplitude subparallel horizons. Additional geophysical analysis, including seismic attribute analysis, reveals that the data has excessive denoising, and that the continuous features are actually a network of polygonal faults. The polygonal faults were identified in two tiers using variance, curvature, dip magnitude, and dip azimuth seismic attributes. Inline and crossline sections show continuous reflectors with a noisy appearance, where the polygonal faults are suppressed. In the variance time slices, the polygonal fault system forms a complex network that is not clearly imaged in the seismic amplitude data. The patterns of polygonal fault systems in this legacy dataset are compared to more recently acquired 3D seismic data from Australia and New Zealand. It is relevant to emphasize the importance of seismic attribute analysis to improve accuracy of interpretations, and also to not dismiss older seismic data that has low accurate imaging, as the variable amplitude subparallel horizons might have a geologic origin.

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Minibasin mobility and obstruction on salt-detached slopes: implications for canopy dynamics and sediment routing

10.5194/egusphere-egu2020-11125 ◽

2020 ◽

Author(s):

Naiara Fernandez ◽

Oliver Duffy ◽

Frank Peel ◽

Michael Hudec ◽

Gillian Apps ◽

...

Keyword(s):

Large Scale ◽

Early Stage ◽

Regional Scale ◽

Local Strain ◽

Seismic Attribute ◽

Structural Domains ◽

Hydrocarbon Reservoir ◽

Sediment Routing ◽

Attribute Analysis ◽

The Individual

In salt-detached gravity-gliding/spreading systems the detachment geometry is a key control on the downslope mobility of the supra-canopy (supra-salt) sequence. As supra-canopy minibasins translate downslope, they also subside into salt. If the base of salt has high relief, minibasins may weld and stop from further free translation downslope. The degree of minibasin obstruction controls both the kinematics of the individual basins, and the more regional pattern of supra-canopy strain.&#160;Here, we use regional 3D seismic data to examine a salt-stock canopy in the northern Gulf of Mexico slope, in an area where supra-canopy minibasins subsided vertically and translated downslope above a complex base-of-salt with high relief.At a regional scale, we distinguish two structural domains in the study area: a highly obstructed or locked domain and a highly mobile domain. Large-scale translation of the supra-canopy sequence is recorded in the mobile domain by two different structures (a far-travelled minibasin and a ramp syncline basin). Although identifying the deformation area between the two regional domains is challenging due to its diffusive nature, characterizing domains according to base-of-salt geometry and supra-canopy minibasin configuration is helpful in identifying structural domains that may share similar subsidence and downslope translation histories.At minibasin scale, minibasins that become obstructed modify the local strain field, typically developing a zone of shortening immediately updip of it and an extensional breakaway zone immediately downdip. Seismic attribute analysis performed in a cluster of minibasins in the study area illustrates a long-lived sediment transport system affected by the complex strain patterns associated with minibasin obstruction. At an early stage, a submarine channel system is captured and subsequently rerouted in response to the updip shortening associated with minibasin obstruction. At a later stage, a mass-transport complex (MTC) is steered by the topographic barrier created by the downdip extensional breakaway associated with minibasin obstruction.Our work illustrates how salt-tectonic processes related to minibasin obstruction can affect the canopy dynamics at both regional and minibasin scale. Furthermore, we show that minibasin obstruction processes can modify the seafloor and subsequently control deepwater sediment dispersal, which, ultimately can affect hydrocarbon reservoir distribution on salt-influenced slopes

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Along-strike structure segmentation and cross-strike transfer faults in the Middle Devonian Marcellus Shale, Pennsylvania, Central Appalachian Basin: Implications for gas recovery efficiency and risk assessment using 3D seismic attribute analysis

10.1190/segam2013-1309.1 ◽

2013 ◽

Author(s):

Emily D. Roberts ◽

Dengliang Gao

Keyword(s):

Risk Assessment ◽

Middle Devonian ◽

Marcellus Shale ◽

Appalachian Basin ◽

Recovery Efficiency ◽

3D Seismic ◽

Seismic Attribute ◽

Gas Recovery ◽

Attribute Analysis ◽

Transfer Faults

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THE DIRKALA SOUTH OIL DISCOVERY: FOCUSSING ON COST-EFFICIENT RESERVOIR DELINEATION

The APPEA Journal ◽

10.1071/aj94004 ◽

1995 ◽

Vol 35 (1) ◽

pp. 65

Author(s):

S.I. Mackie ◽

C.M. Gumley

Keyword(s):

Production Performance ◽

Seismic Survey ◽

3D Seismic ◽

Seismic Attribute ◽

Data Set ◽

Seismic Surveys ◽

Seismic Modelling ◽

Attribute Analysis ◽

Cost Efficient ◽

The Cost

The Dirkala Field is located in the southern Murta Block of PEL's 5 and 6 in the southern Cooper and Eromanga Basins. Excellent oil production from a single reservoir sandstone in the Jurassic Birkhead Formation in Dirkala-1 had indicated a potentially larger resource than could be mapped volumetrically. The hypothesis that the resource was stratigraphically trapped led to the need to define the fluvial sand reservoir seismically and thereby prepare for future development.A small (16 km2) 3D seismic survey was acquired over the area in December 1992. The project was designed not only to evaluate the limits of the Birkhead sand but also to evaluate the cost efficiency of recording such small 3D surveys in the basin.Interpretation of the data set integrated with seismic modelling and seismic attribute analysis delineated a thin Birkhead fluvial channel sand reservoir. Geological pay mapping matched volumetric estimates from production performance data. Structural mapping showed Dirkala-1 to be optimally placed and that no further development drilling was justifiable.Seismic characteristics comparable with those of the Dirkala-1 Birkhead reservoir were noted in another area of the survey beyond field limits. This led to the proposal to drill an exploration well, Dirkala South-1, which discovered a new oil pool in the Birkhead Formation. A post-well audit of the pre-drill modelling confirmed that the seismic response could be used to determine the presence of the Birkhead channel sand reservoir.The acquisition of the Dirkala-3D seismic survey demonstrated the feasibility of conducting small 3D seismic surveys to identify subtle stratigraphically trapped Eromanga Basin accumulations at lower cost and risk than appraisal/development drilling based on 2D seismic data.

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Identification of Infill and Step-Out Drilling Potential Via Acoustic Inversion, 3D Seismic Attribute Analysis, and 3D Seismic Curvature Analysis: Neuquen and San Jorge Basins, Argentina

10.2118/122968-ms ◽

2009 ◽

Author(s):

Scott Haberman ◽

Mariana Aguiar ◽

Jose Antonio Cavero ◽

Victor Sancho Costa ◽

Miguel Mendez ◽

...

Keyword(s):

3D Seismic ◽

Seismic Attribute ◽

Curvature Analysis ◽

Attribute Analysis ◽

Acoustic Inversion

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Geopressure prediction using seismic data: Current status and the road ahead

Geophysics ◽

10.1190/1.1527101 ◽

2002 ◽

Vol 67 (6) ◽

pp. 2012-2041 ◽

Cited By ~ 120

Author(s):

N. C. Dutta

Keyword(s):

Seismic Data ◽

Large Scale ◽

Best Practice ◽

Seismic Velocity ◽

Rock Physics ◽

Rock Properties ◽

Current Status ◽

Seismic Attribute ◽

Attribute Analysis ◽

Exploration And Production

The subject of seismic detection of abnormally high‐pressured formations has received a great deal of attention in exploration and production geophysics because of increasing exploration and production activities in frontier areas (such as the deepwater) and a need to lower cost without compromising safety and environment, and manage risk and uncertainty associated with very expensive drilling. The purpose of this review is to capture the “best practice” in this highly specialized discipline and document it. Pressure prediction from seismic data is based on fundamentals of science, especially those of rock physics and seismic attribute analysis. Nonetheless, since the first seismic application in the 1960s, practitioners of the technology have relied increasingly on empiricism, and the fundamental limitations of the tools applied to detect such hazardous formations were lost. The most successful approach to seismic pressure prediction is one that combines a good understanding of rock properties of subsurface formations with the best practice for seismic velocity analysis appropriate for rock physics applications, not for stacking purposes. With the step change that the industry has seen in the application of the modern digital computing technology to solving large‐scale exploration and production problems using seismic data, the detection of pressured formations can now be made with more confidence and better resolution. The challenge of the future is to break the communication and the “language barrier” that still exists between the seismologists, the rock physicists, and the drilling community.

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Investigation of seismic attributes, depositional environments, and hydrocarbon sweet-spot distribution in the Serbin field, Taylor Formation, Southeast Texas

Interpretation ◽

10.1190/int-2018-0041.1 ◽

2019 ◽

Vol 7 (1) ◽

pp. T49-T66

Author(s):

Osareni C. Ogiesoba ◽

William A. Ambrose ◽

Robert G. Loucks

Keyword(s):

Acoustic Impedance ◽

Depositional Environments ◽

High Resistivity ◽

3D Seismic ◽

Seismic Attribute ◽

Seismic Amplitude ◽

Attribute Analysis ◽

Property Versus ◽

Multiattribute Analysis ◽

Sweet Spots

We have conducted seismic-attribute analysis at the Serbin field — in an area straddling Lee, Fayette, and Bastrop Counties and covering approximately [Formula: see text] (approximately [Formula: see text]) — using new, reprocessed, 3D seismic data to provide additional understanding of depositional environments and better predict the distribution of hydrocarbon sweet spots. We converted the 3D seismic volume into a log-lithology volume and integrated core data to examine the distribution of lithology and interpret depositional environments. By conducting multiattribute analysis, we predicted resistivity (deep-induction log) volume and generated a resistivity map to identify hydrocarbon sweet spots. Our results show that reservoir sandstones in the Serbin field are storm-dominated, shelf-sand deposits. Although individual sandstone beds are lenticular and discontinuous, they collectively constitute a sheet-like geometry, trending northeast to southwest. On the basis of resistivity maps and rock property versus seismic-amplitude crossplots, we differentiated reservoirs in the lower Taylor Formation into two zones: (1) a northwest, high-resistivity, high-acoustic impedance zone and (2) a southeast, low-resistivity, low-acoustic impedance zone. The results also indicated that hydrocarbon sweet spots in the Serbin field are characterized by high resistivity and high impedance. Furthermore, the log-lithology method, although fast and effective, is limited because it cannot take into account sandstone zones having low acoustic impedance.

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3D seismic attributes for a tight gas sand reservoir characterization of the eastern Sulige gas field, Ordos Basin, China

Geophysics ◽

10.1190/geo2014-0362.1 ◽

2015 ◽

Vol 80 (2) ◽

pp. B35-B43 ◽

Cited By ~ 12

Author(s):

Zhiguo Wang ◽

Jinghuai Gao ◽

Daxing Wang ◽

Qiansheng Wei

Keyword(s):

Ordos Basin ◽

Seismic Attributes ◽

Gas Production ◽

Seismic Attenuation ◽

Tight Gas ◽

3D Seismic ◽

Seismic Attribute ◽

Gas Field ◽

Attribute Analysis ◽

Phase Tuning

The Lower Permian Xiashihezi Formation of the Ordos Basin is the largest producer of tight gas sand in China. The controls on tight gas production are many and include a variety of geologic, hydrodynamic, and engineering factors from one well to another throughout the basin. In this study, we considered data from a [Formula: see text] 3D seismic volume and logs from 17 wells to investigate the geologic controls on gas production in the [Formula: see text] member of the Xiashihezi Formation, eastern Sulige gas field, Ordos Basin. Our objective was to determine the potential of applying multiple seismic attributes to identify the higher productivity areas of a tight gas sand reservoir. To achieve this, we used amplitude, complex traces, spectral decomposition, and seismic attenuation attributes derived from the 3D seismic volume to detect gas-bearing sand areas. The results of seismic attribute analysis revealed that no single attribute is correlated to higher productivity areas. The qualitative correlations between attributes and production records reflected that higher productivity areas are associated with seismically definable higher amplitude, more stable phase, tuning frequency, and stronger attenuation features in the study area. Meanwhile, three outlier wells in the seismic attribute analysis provided a reminder of the uncertainty in geologic interpretation. The gas-sand reservoir evaluation results suggested that the Pareto principle helps to enhance the interpretation needed to determine the productivity distribution of [Formula: see text] tight-gas reservoir in the study area.

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