Difference between revisions of "Critical elements application: Niobrara example"
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| part = | | part = | ||
| chapter = Developing a philosophy of exploration | | chapter = Developing a philosophy of exploration | ||
| − | | frompg = 1- | + | | frompg = 1-34 |
| − | | topg = 1- | + | | topg = 1-36 |
| author = Edward A. Beaumont, Norman H. Foster, Richard R. Vincelette, Marlan W. Downey, James D. Robertson | | author = Edward A. Beaumont, Norman H. Foster, Richard R. Vincelette, Marlan W. Downey, James D. Robertson | ||
| link = http://archives.datapages.com/data/specpubs/beaumont/ch01/ch01.htm | | link = http://archives.datapages.com/data/specpubs/beaumont/ch01/ch01.htm | ||
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* Maximum bed curvature | * Maximum bed curvature | ||
| − | * [[ | + | * [[Normal fault]] cutting through area of maximum bed curvature |
* Presence of a cross-lineation | * Presence of a cross-lineation | ||
| − | * Open calcite crystals lining the fractures | + | * [[Open calcite crystals]] lining the fractures |
* Well must penetrate above critical elements in a more fracturable (more calcareous) bench within the Niobrara | * Well must penetrate above critical elements in a more fracturable (more calcareous) bench within the Niobrara | ||
| − | * Completion must be [[Well completions#Open hole completions|open hole]] (hang a [[Well completions#Liner completions|slotted liner]]) with cement-block | + | * Completion must be [[Well completions#Open hole completions|open hole]] (hang a [[Well completions#Liner completions|slotted liner]]) with [[cement-block fracture]]s |
| − | * Drilling must be conducted with [[Analysis of mud weights|underbalanced mud]] or air to prevent fracture damage. The Niobrara is an [[Causes of underpressure|underpressured reservoir]] with petrostatic (0.33 lb/ft gradient) rather than [[Normal hydrostatic pressure|hydrostatic]] (0.43 lb/ft gradient) pressure. | + | * Drilling must be conducted with [[Analysis of mud weights|underbalanced mud]] or air to prevent fracture damage. The Niobrara is an [[Causes of underpressure|underpressured reservoir]] with [[Geostatic and lithostatic pressure|petrostatic]] (0.33 lb/ft gradient) rather than [[Normal hydrostatic pressure|hydrostatic]] (0.43 lb/ft gradient) pressure. |
==Applying the critical factors== | ==Applying the critical factors== | ||
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==Niobrara structure== | ==Niobrara structure== | ||
| − | [[file:developing-a-philosophy-of-exploration_fig1-2.png|thumb|{{figure number|1}}An example Niobrara structure map.]] | + | [[file:developing-a-philosophy-of-exploration_fig1-2.png|thumb|300px|{{figure number|1}}An example Niobrara structure map.]] |
| − | In the Niobrara play, a subsurface [[Subsurface maps#Structure|structure map]] on top of the Niobrara formation is a first step to locate areas of maximum bed curvature. [[ | + | In the Niobrara play, a subsurface [[Subsurface maps#Structure|structure map]] on top of the Niobrara formation is a first step to locate areas of maximum bed curvature. [[Normal fault]]s should then be mapped from subsurface well control, [[Remote sensing|photogeology]], and good old-fashioned [[The seven critical elements of fieldwork|field work]]. Cross-linears may be mapped from photogeology and [[Remote sensing|satellite imagery]]. [[:file:developing-a-philosophy-of-exploration_fig1-2.png|Figure 1]] is an example Niobrara structure map. |
==Niobrara maximum bed curvature== | ==Niobrara maximum bed curvature== | ||
| − | [[file:developing-a-philosophy-of-exploration_fig1-3.png|thumb|{{figure number|2}}A Niobrara structure cross section.]] | + | [[file:developing-a-philosophy-of-exploration_fig1-3.png|300px|thumb|{{figure number|2}}A Niobrara structure cross section.]] |
| − | Higher resistivity on electrical logs shows the brittle, more fracturable benches within the Niobrara. Constructing a detailed [[Geological cross sections|cross section]], showing fracturable benches, maximum bed curvature, and any surface and subsurface [[Fault trap regime|normal fault]]ing, allows the explorer to visualize and accurately plot the angle at which the well bore must be drilled to penetrate the critical elements. | + | Higher [[resistivity]] on electrical logs shows the [[Brittleness|brittle]], more fracturable benches within the Niobrara. Constructing a detailed [[Geological cross sections|cross section]], showing fracturable benches, maximum bed curvature, and any surface and subsurface [[Fault trap regime|normal fault]]ing, allows the explorer to visualize and accurately plot the angle at which the well bore must be drilled to penetrate the critical elements. |
| − | Seismic surveys are not particularly helpful in mapping normal faults because they are [[Fault trap regime|listric]] with about 100-300 ft of throw at the surface and about 30-80 ft of throw in the Niobrara. The faults are usually not present below the Niobrara. Therefore, although the Mesa Verde provides good seismic marker beds, the underlying Mancos and Niobrara | + | Seismic surveys are not particularly helpful in mapping normal faults because they are [[Fault trap regime|listric]] with about 100-300 ft of [[throw]] at the surface and about 30-80 ft of throw in the Niobrara. The faults are usually not present below the Niobrara. Therefore, although the Mesa Verde provides good [[seismic marker]] beds, the underlying Mancos and Niobrara |
| − | Formations usually do not have them. Occasionally, upward-lying normal faults will produce. [[Seismic data]] are useful in delineating these faults because good marker beds are usually present below the Niobrara. The fault can then be projected upward and is sometimes associated with a dim spot due to [[Vertical and lateral seismic resolution and attenuation#Attenuation|attenuation]] of [[seismic data]] in fracture zones. | + | Formations usually do not have them. Occasionally, upward-lying normal faults will produce. [[Seismic data]] are useful in delineating these faults because good marker beds are usually present below the Niobrara. The fault can then be projected upward and is sometimes associated with a [[dim spot]] due to [[Vertical and lateral seismic resolution and attenuation#Attenuation|attenuation]] of [[seismic data]] in fracture zones. |
[[:file:developing-a-philosophy-of-exploration_fig1-3.png|Figure 2]] is a Niobrara structure cross section. | [[:file:developing-a-philosophy-of-exploration_fig1-3.png|Figure 2]] is a Niobrara structure cross section. | ||
==Niobrara open fractures== | ==Niobrara open fractures== | ||
| − | [[Overview of routine core analysis|Running samples]] on Niobrara wells will reveal whether open calcite crystals are present in the fractures. In addition, [[The seven critical elements of fieldwork|field work]] has shown that the same kind of calcite present in subsurface fractures within the Niobrara also occurs in fractures associated with brittle beds at the surface, such as the Mesa Verde group. | + | [[Overview of routine core analysis|Running samples]] on Niobrara wells will reveal whether [[open calcite crystals]] are present in the fractures. In addition, [[The seven critical elements of fieldwork|field work]] has shown that the same kind of calcite present in subsurface fractures within the Niobrara also occurs in fractures associated with brittle beds at the surface, such as the Mesa Verde group. |
==Surface geochemistry applied to Niobrara play== | ==Surface geochemistry applied to Niobrara play== | ||
| − | [[Principles of surface geochemical exploration|Surface geochemical methods]]—specifically, [[Seepage activity|soil gas]] surveys—have proven useful in exploring for these types of traps. The computer compares hundreds of soil-gas ratios very quickly. Also, very sensitive chromatographs have improved the detection of vertical microseepages of hydrocarbons above these fractured reservoirs. The main method of exploration with this technique is to conduct surveys over a number of known commercial accumulations to establish productive | + | [[Principles of surface geochemical exploration|Surface geochemical methods]]—specifically, [[Seepage activity and surficial geochemistry|soil gas]] surveys—have proven useful in exploring for these types of traps. The computer compares hundreds of soil-gas ratios very quickly. Also, very sensitive [[chromatographs]] have improved the detection of vertical microseepages of hydrocarbons above these fractured reservoirs. The main method of exploration with this technique is to conduct surveys over a number of known commercial accumulations to establish [[productive signature]]s. Then a survey over the prospect may provide useful information that can be integrated with the other exploration techniques to help locate a drillsite. |
==Conclusion== | ==Conclusion== | ||
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[[Category:Value of geological fieldwork]] | [[Category:Value of geological fieldwork]] | ||
[[Category:Traps, trap types, and the petroleum system]] | [[Category:Traps, trap types, and the petroleum system]] | ||
| + | [[Category:Examples]] | ||
| + | [[Category:Treatise Handbook 3]] | ||
Latest revision as of 16:03, 18 February 2022
| Exploring for Oil and Gas Traps | |
| |
| Series | Treatise in Petroleum Geology |
|---|---|
| Chapter | Developing a philosophy of exploration |
| Author | Edward A. Beaumont, Norman H. Foster, Richard R. Vincelette, Marlan W. Downey, James D. Robertson |
| Link | Web page |
| Store | AAPG Store |
Critical elements of the Niobrara play
In the fractured Upper Cretaceous Niobrara play of the central Rocky Mountain region, specific critical elements must be present for a prospect to be successful. Since the Niobrara Formation is its own oil source rock, there is no bottom water; gas expansion along with gravity drainage provide the main reservoir energy, so the structural position of a well is not a critical factor. Synclines, anticlines, and any structural location in between will work. The main critical element is to find a sufficiently fractured sweet spot in which the fractures remain open during production. Careful study of numerous excellent Niobrara producing fields shows that the following critical elements must be present to achieve commercial success.
- Maximum bed curvature
- Normal fault cutting through area of maximum bed curvature
- Presence of a cross-lineation
- Open calcite crystals lining the fractures
- Well must penetrate above critical elements in a more fracturable (more calcareous) bench within the Niobrara
- Completion must be open hole (hang a slotted liner) with cement-block fractures
- Drilling must be conducted with underbalanced mud or air to prevent fracture damage. The Niobrara is an underpressured reservoir with petrostatic (0.33 lb/ft gradient) rather than hydrostatic (0.43 lb/ft gradient) pressure.
Applying the critical factors
Once the critical factors from the analog field(s) are fully understood, we can devise the best exploration methods to delineate the critical factors.
Niobrara structure
In the Niobrara play, a subsurface structure map on top of the Niobrara formation is a first step to locate areas of maximum bed curvature. Normal faults should then be mapped from subsurface well control, photogeology, and good old-fashioned field work. Cross-linears may be mapped from photogeology and satellite imagery. Figure 1 is an example Niobrara structure map.
Niobrara maximum bed curvature
Higher resistivity on electrical logs shows the brittle, more fracturable benches within the Niobrara. Constructing a detailed cross section, showing fracturable benches, maximum bed curvature, and any surface and subsurface normal faulting, allows the explorer to visualize and accurately plot the angle at which the well bore must be drilled to penetrate the critical elements.
Seismic surveys are not particularly helpful in mapping normal faults because they are listric with about 100-300 ft of throw at the surface and about 30-80 ft of throw in the Niobrara. The faults are usually not present below the Niobrara. Therefore, although the Mesa Verde provides good seismic marker beds, the underlying Mancos and Niobrara
Formations usually do not have them. Occasionally, upward-lying normal faults will produce. Seismic data are useful in delineating these faults because good marker beds are usually present below the Niobrara. The fault can then be projected upward and is sometimes associated with a dim spot due to attenuation of seismic data in fracture zones.
Figure 2 is a Niobrara structure cross section.
Niobrara open fractures
Running samples on Niobrara wells will reveal whether open calcite crystals are present in the fractures. In addition, field work has shown that the same kind of calcite present in subsurface fractures within the Niobrara also occurs in fractures associated with brittle beds at the surface, such as the Mesa Verde group.
Surface geochemistry applied to Niobrara play
Surface geochemical methods—specifically, soil gas surveys—have proven useful in exploring for these types of traps. The computer compares hundreds of soil-gas ratios very quickly. Also, very sensitive chromatographs have improved the detection of vertical microseepages of hydrocarbons above these fractured reservoirs. The main method of exploration with this technique is to conduct surveys over a number of known commercial accumulations to establish productive signatures. Then a survey over the prospect may provide useful information that can be integrated with the other exploration techniques to help locate a drillsite.
Conclusion
Critical elements of the Niobrara play were identified by studying known accumulations. Knowing what elements were critical allowed a focused effort that saved time and improved effectiveness. Study known examples of trap types of interest to discover critical elements, and the result will be a more effective program.
See also
External links
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