Brushy Canyon Research Articles

ABSTRACT: Lithology and Fluids: Seismic Models of the Brushy Canyon Formation, West Texas

ABSTRACT: Lithology and Fluids: Seismic Models of the Brushy Canyon Formation, West Texas

ABSTRACT: Criteria for Defining the Base-of-Slope for Deep Water Clastic Systems, Upper Brushy Canyon Formation, West Texas

ABSTRACT: Criteria for Defining the Base-of-Slope for Deep Water Clastic Systems, Upper Brushy Canyon Formation, West Texas

Abstract: Submarine channel architecture along a slope to basin profile, Brushy Canyon Formation, West Texas

Abstract: Submarine channel architecture along a slope to basin profile, Brushy Canyon Formation, West Texas

Abstract: Submarine fan architecture along a slope to basin profile, Brushy Canyon Formation, West Texas

Abstract: Submarine fan architecture along a slope to basin profile, Brushy Canyon Formation, West Texas

Abstract: Deciphering proximal/distal from along-strike variations in submarine channel architecture in the Permian middle Brushy Canyon Formation, West Texas

Abstract: Deciphering proximal/distal from along-strike variations in submarine channel architecture in the Permian middle Brushy Canyon Formation, West Texas

ABSTRACT: An Evaluation of the Source Rock, Reservoir Rock, and Sequence Stratigraphy for the Brushy Canyon Formation's Hydrocarbon Accumulations of the Delaware Basin, Southeastern New Mexico

ABSTRACT: An Evaluation of the Source Rock, Reservoir Rock, and Sequence Stratigraphy for the Brushy Canyon Formation's Hydrocarbon Accumulations of the Delaware Basin, Southeastern New Mexico

Abstract: Application of results from outcrops of the deep-marine Brushy Canyon Formation, Delaware Basin, as analogues for the deep-marine exploration targets on the Norwegian Shelf

Abstract: Application of results from outcrops of the deep-marine Brushy Canyon Formation, Delaware Basin, as analogues for the deep-marine exploration targets on the Norwegian Shelf

Delaware Mountain Group, West Texas, A Case of Refound Opportunity: Part 2--Cherry Canyon Formation (E & P Notes)

Recent drilling activity in the War-Wink area of west Texas has established a new play in submarine channel and levee/overbank sandstones of the middle and lower Cherry Canyon Formation, Delaware Mountain Group (Guadalupian). Previous exploration and development, spanning the 1960s, 1970s, and early 1980s, had focused on the upper part of the formation. The new play, located a few miles west of the Central Basin platform, suggests the existence of multiple channel trends not yet explored in the Delaware basin. Entrapment in the War-Wink area is related to both structural and stratigraphic factors. Lower Cherry Canyon reservoirs have porosities ranging from 18 to 24% and permeabilities ranging from 10 to 60 md and thus are higher in quality than reservoirs of the underlying Brushy Canyon Formation. Core data indicate that permeabilities increase rapidly above a threshold porosity value of about 18%. Lower Cherry Canyon wells are completed by fracture stimulation in one or two main reservoir zones, with several secondary zones commonly behind pipe. Wells usually flow at rates of 100-200 bbl oil per day for up to 1 yr before being put on pump. Main producing zones are capable of recoveries ranging from 50,000 to 120,000 bbl. Attempts at using horizontal drilling in place of fracture stimulation have proved highly successful in certain cases. Use of this approach for Cherry Canyon development, guided by good geologic control, may provide an excellent technique applicable to many portions of the Delaware basin.

Reservoir Characterization as a Risk-Reduction Tool at the Nash Draw Pool

Summary Recently acquired geological, geophysical, and engineering data at the Nash Draw Brushy Canyon Pool revealed that the initial reservoir characterization was too simplistic to capture the critical features of this complex Delaware formation. A new reservoir description provides sufficient detail to indicate that compartmentalization exists in the Brushy Canyon interval. This new reservoir description is being used to identify "sweet spots" for a development drilling program as well as to optimize reservoir management strategies. This paper presents recent results of an integrated reservoir characterization effort that is being used at Nash Draw as a risk reduction tool.

Delaware Mountain Group, West Texas and Southeastern New Mexico, A Case of Refound Opportunity: Part 1--Brushy Canyon

Exploration in Permian (Guadalupian) deep-water sandstones of the Delaware Mountain Group, west Texas and southeast New Mexico, represents a success story of the 1990s derived from reevaluation of reservoirs previously deemed uneconomical. Recent discoveries have concentrated on the Brushy Canyon in New Mexico and, to a lesser extent, the Cherry Canyon in Texas. Brushy Canyon reservoirs in particular previously were overlooked due to indications of poor reservoir quality from log and well test data; however, oil shows observed on mud logs across the northern Delaware basin led to new completion efforts in the late 1980s and 1990s using gel-sand fracture stimulations. Productive reservoirs are very fine to fine-grained arkosic to subarkosic sandstones with porosities of 12-25% and permeabilities typically of 1-5 md. Better reservoir quality is concentrated in massive channel sandstones variably interpreted as deposited by turbidity or saline density currents. Significant clay content, lamination, and close interbedding between oil- and water-bearing units make log analysis and reserve estimates problematic. As a result, the mud log remains the cheapest, most practical indicator of pay. Reservoir sandstones can be divided into a series of major productive trends related to proximal/slope and more distal/basin-floor depositional settings. Well productivity is variable within each trend, but primary recovery rarely exceeds 10%. Options for enhanced recovery include pressure maintenance, waterflooding, and carbon dioxide flooding. Early indications suggest that carbon dioxide flooding may be most appropriate in these low-permeability, clay-bearing reservoirs.

Abstract: Stratigraphic Hierarchy of Organic Carbon-Rich Siltstones in Deep-Water Facies, Brushy Canyon Formation (Guadalupian), Delaware Basin, Texas 

Abstract: Stratigraphic Hierarchy of Organic Carbon-Rich Siltstones in Deep-Water Facies, Brushy Canyon Formation (Guadalupian), Delaware Basin, Texas 

Abstract: The Permian Brushy Canyon Formation Submarine Fan Complex of West Texas: Implications to Sequence Stratigraphic Models for Deep-Water Clastics 

Abstract: The Permian Brushy Canyon Formation Submarine Fan Complex of West Texas: Implications to Sequence Stratigraphic Models for Deep-Water Clastics 

3-D seismic imaging and interpretation of Brushy Canyon slope and basin thin‐bed reservoirs, northwest Delaware Basin

A study was done at Nash Draw field, Eddy County, New Mexico, to demonstrate how engineering, drilling, geologic, geophysical, and petrophysical technologies should be integrated to improve oil recovery from Brushy Canyon reservoirs at depths of approximately 6600 ft (2000 m) on the northwest slope of the Delaware basin. These thin‐bed reservoirs were deposited in a slope‐basin environment by a mechanism debated by researchers, a common model being turbidite deposition. In this paper, we describe how state‐of‐the‐art 3-D seismic data were acquired, interpreted, integrated with other reservoir data, and then used to improve the sitting of in‐field wells and to provide facies parameters for reservoir simulation across this complex depositional system. The 3-D seismic field program was an onshore subsalt imaging effort because the Ochoan Rustler/Salado, a high‐velocity salt/anhydrite section, extended from the surface to a depth of approximately 3000 ft (900 m) across the entire study area. The primary imaging targets were heterogenous siltstone and fine‐grained sandstone successions approximately 100 ft (30 m) thick and comprised of complex assemblages of thin lobe‐like deposits having individual thickness of 3 to 6 ft (1 to 2 m). The seismic acquisition was complicated further by (1) the presence of active potash mines around and beneath the 3-D grid that were being worked at depths of 500 to 600 ft (150 to 180 m), (2) shallow salt lakes, and (3) numerous archeological sites. We show that by careful presurvey wave testing and attention to detail during data processing, thin‐bed reservoirs in this portion of the Delaware basin can be imaged with a signal bandwidth of 10 to 100 Hz and that siltstone/sandstone successions 100 ft (30 m) thick in the basal Brushy Canyon interval can be individually detected and interpreted. Further, we show that amplitude attributes extracted from these 3-D data are valuable indicators of the amount of net pay and porosity‐feet in the major reservoir successions and of the variations in the fluid transmissivity observed in production wells across the field. Relationships between seismic reflection amplitude and reservoir properties determined at the initial calibration wells have been used to site and drill two production wells. The first well found excellent reservoir conditions; the second well was slightly mispositioned relative to the targeted reflection‐amplitude trend and penetrated reservoir facies typical of that at other producing wells. Relationships between seismic reflection amplitude and critical petrophysical properties of the thin‐bed reservoirs have also allowed a seismic‐driven simulation of reservoir performance to be initiated.

3-D instantaneous frequency used as a coherency/continuity parameter to interpret reservoir compartment boundaries across an area of complex turbidite deposition

In previous unpublished work, we found that anomalous values of instantaneous frequency (that is, frequency values that are negative or that have positive magnitudes greater than Nyquist limit) are valuable indicators of alterations in reflection waveshape that occur commonly at stratigraphic terminations. Inspection of 3-D seismic data across Nash Draw Field on the northwest slope of the Delaware Basin showed that appreciable wavelet alterations occurred at the boundaries of distinct seismic facies within the targeted Brushy Canyon reservoirs that are being produced in this field. Based on this observation, we used instantaneous frequency as the fundamental database to define the edge positions and areal shapes of individual reservoir facies within this complex, slope‐basin distribution of siltstones and sandstones, commonly thought to be a succession of turbidite depositions. We compared the compartmentalization detail derived from this frequency‐based approach with compartmentalization models provided by an amplitude‐based interpretation and by coherency/continuity cube technology. These comparisons led us to conclude that a properly executed 3-D interpretation of instantaneous frequency behavior can provide a good first guess of the internal compartmented structure of many reservoirs. We offer our work here for peer evaluation by people who support reservoir characterization studies similar to what we describe. We have used instantaneous frequency behavior to successfully detect lateral disruptions in stratigraphic continuity for several years—long before the current concept of a coherency (or continuity) cube was publicized for this same purpose. This study shows that interpreters who do not have ready access to coherency‐cube technology, but who do have Hilbert transform algorithms available to them, can create 3-D volumes of instantaneous frequency that provide valuable indications of reflection discontinuity, much in the same way that continuity/coherency cube technology does.

Contaminant transport in sets of parallel finite fractures with fracture skins

Analysis of flow and transport in double/dual-porosity or fractured formations is a problem with important theoretical and practical applications. We present steady-state and transient solutions for solute transport in a finite system of parallel fractures with fracture skins. Solute transport in the fractures is by advection and hydrodynamic dispersion. Concentrations are attenuated by diffusion into the porous matrix. Radioactive decay and sorption in the skin, the matrix, and along the fracture walls are included. Our analysis extends previous studies by considering both finite fracture lengths and the effects of fracture skins. Our results conform to these studies when considering large, but finite fractures without skins. For transient solutions, we use a numerical inversion of the Laplace transforms and also present a series solution. Steady-state solutions are closed form analytical solutions. The results of these analyses can be used for the verification of numerical models used in predicting or retrodicting flow and transport in fractured porous media and for sensitivity analyses. The steady-state analyses are shown to be satisfactory for sensitivity analyses. We utilize data for cesium-137 and from the Permian Brushy Canyon Sandstone of west Texas in the sensitivity analyses to show the effects of fracture skins. The analyses indicate increased distances of transport with thicker skins of lower porosity and lower diffusivity. Retardation effects were smaller in magnitude. Analysis of transport in dual-porosity systems should consider the effects of fracture skins because they are ubiquitous in nature and are present in many, if not most, hydraulically active near-surface fractures.

Abstract: Portrait of a Basin-Floor Fan for Sandy Deep-Water Systems, Permian Lower Brushy Canyon Fm., Delaware Mountains, West Texas

Abstract: Portrait of a Basin-Floor Fan for Sandy Deep-Water Systems, Permian Lower Brushy Canyon Fm., Delaware Mountains, West Texas

Abstract: Slope to Basin floor Variations in Channel Geometry and Reservoir Architecture, Brushy Canyon Formation, Permian, West Texas

Abstract: Slope to Basin floor Variations in Channel Geometry and Reservoir Architecture, Brushy Canyon Formation, Permian, West Texas

Abstract: Mudstone Facies of the Upper Brushy Canyon Formation and Getaway Limestone: Insights Into Depositional Processes and Stratigraphic Distribution

Abstract: Mudstone Facies of the Upper Brushy Canyon Formation and Getaway Limestone: Insights Into Depositional Processes and Stratigraphic Distribution

Abstract: Stratigraphic Hierarchy of Organic Carbon-Rich Siltstones in Deep-Water Facies, Brushy Canyon Formation (Guadalupian), Delaware Basin, Texas

Abstract: Stratigraphic Hierarchy of Organic Carbon-Rich Siltstones in Deep-Water Facies, Brushy Canyon Formation (Guadalupian), Delaware Basin, Texas

Stratigraphic hierarchy of organic carbon–rich siltstones in deep-water facies, Brushy Canyon Formation (Guadalupian), Delaware Basin, West Texas

The first systematic test for a predictive relationship between organic carbon content and stratigraphic hierarchy in a deep-water slope to basin-floor deposit was performed. The studied section includes the Pipeline Shale, the Brushy Canyon Formation, and the lower part of the Cherry Canyon Formation of the Delaware Mountain Group, West Texas. This interval represents one large-scale, 3rd-order genetic sequence within which 4th- and 5th-order stratigraphic cycles are recognized. Samples of fine-grained facies throughout the section were collected from outcrop and analyzed for organic carbon content and hydrogen index. Degree of pyritization was also determined for a subset of the samples. The results indicate that organic enrichment is closely correlated to the stratigraphic hierarchy at the 3rd-, 4th-, and 5th-order levels. The data suggest that quantity and quality of preserved organic matter are controlled by changes in bulk sedimentation rate (dilution vs. condensation), which affect organic matter inputs to the sediment, as well as the balance between (1) burial and preservation of organic matter and (2) its degradation on the sea floor during times of sediment starvation.