--> Reservoirs Without Seismic Reflection Signal, by Bob Hardage, #40261 (2007).
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GCReservoirs Without Seismic Previous HitReflectionNext Hit Signal*

By

Bob Hardage1

 
Search and Discovery Article #40261 (2007)
Posted October 10, 2007
 
*Adapted from the Geophysical Corner column, prepared by the author, in AAPG Explorer, September, 2007, and entitled “No Previous HitReflectionNext Hit Signal Can Be Good.” Editor of Geophysical Corner is Bob A. Hardage. Managing Editor of AAPG Explorer is Vern Stefanic; Larry Nation is Communications Director.
 
1Bureau of Economic Geology, The University of Texas at Austin ([email protected])
 

General Statement 

As seismic interpreters, most of us – including the author – have developed the mindset that robust Previous HitreflectionNext Hit events are what we first try to associate with drilling targets. For thin-bed units, Previous HitreflectionNext Hit amplitude increases as net pay increases within the target interval. Thin-bed interpreters conclude that “strong Previous HitreflectionNext Hit events are good.”  

In a sand-shale sequence, gas reservoirs produce P-wave bright spots. In this type of geology, interpreters focus on the boldest Previous HitreflectionNext Hit signals to define drilling targets. Depending on the nature of the seismic impedance contrasts in the type of geology that is being interpreted, there are exceptions to these two examples that drilling targets are associated with reasonably prominent Previous HitreflectionNext Hit events. However, the association between robust Previous HitreflectionNext Hit responses and drilling targets is successfully applied across many prospects and in several depositional environments. In this article, we look at the opposite Previous HitprincipleNext Hit and describe a drilling target for which the correct mindset is: “Drill where there is no Previous HitreflectionNext Hit signal.”

 

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uGeneral Statement

uFigure Captions

uExample

uConclusion

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

uGeneral Statement

uFigure Captions

uExample

uConclusion

Figure Captions

Figure 1. Map of a targeted thin Caddo sandstone drilling target developed from an interpretation of well logs.

Figure 2. Seismic sections along Profile AA’ (left) and Profile BB’ (right) shown on the map in Figure 1. The top of the Caddo interval is identified on each profile. The circled area on each section shows where the sandstone trend crosses the line of profile.

Figure 3. Map of average negative amplitude in a thin 30-ms window immediately below the Caddo horizon defined in Figure 2. The trend of weak Previous HitreflectionNext Hit signal, labeled Channel-fill response range, is the drilling target.

 

Example 

The target in this example is a thin Caddo sandstone positioned at the top of the Bend Conglomerate interval in the Fort Worth Basin. Distribution of the sandstone is shown in map view in Figure 1. This map, based on the interpretation of well logs acquired in the labeled wells, indicates that the sandstone is distributed along a southwest-to-northeast channel-like trend.  

Local operators consider this particular sandstone to be an attractive drilling target, even though the average thickness is only five meters (16 feet). At this location, the Caddo is interpreted to have been deposited in a deltaic environment that had a low accommodation space. Incised channels similar in size and shape to the trend shown in this map are therefore not unexpected features.  

Two profiles (AA’ and BB’) are shown that traverse the sandstone trend and connect key calibration wells. Seismic responses along these profiles are exhibited in Figure 2. The interpreted Caddo horizon is shown on the seismic sections; the circled area on each profile identifies the intersection with the sandstone trend. Outside the circled areas, the Caddo Previous HitreflectionNext Hit is robust because a thin carbonate layer extends across this local area and creates a significant P-wave impedance contrast with the overlying shale. Inside each circled area, the Caddo Previous HitreflectionNext Hit is absent, or minimal, because there is no significant P-wave impedance contrast between the sandstone that infilled the erosional channel and its sealing shale.

 

Conclusion 

To position a well that will penetrate this particular sand, an interpreter has to adopt the attitude that “no Previous HitreflectionNext Hit signal is good.” To illustrate this Previous HitprincipleNext Hit, the average Previous HitreflectionNext Hit trough amplitude calculated in a narrow 30-ms window immediately below the top of the Caddo horizon is displayed as Figure 3. The low-amplitude, southwest-to northeast response, labeled Channel-fill response range on the color bar, identifies the targeted incised channel that downcut through the thin carbonate layer and then was infilled with sand. This no-Previous HitreflectionTop trend is the drilling target. 

The wells shown in these figures were drilled before the 3-D seismic data were acquired. Note the situation for the BYTS14 and BYTS11 wells. BYTS14 touched the edge of the incised channel and produced; BYTS11 was an ever-so-close near miss (Figures 2 and 3).

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