--> Three-Dimensional Prestack Inversion, Lobo Trend, South Texas, Phil Anno, Mark Wuenscher, Robert Corbin, John Hooper, and Frank Chlumsky, #10039 (2003)
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Three-Dimensional Prestack Previous HitInversionNext Hit, Lobo Trend, South Texas*

By

Phil Anno1, Mark Wuenscher1, Robert Corbin1, John Hooper1, and Frank Chlumsky2

Search and Discovery Article #10039 (2003)

 

*Adapted Previous HitfromNext Hit “extended abstract” of presentation at AAPG Annual Meeting, March 10-12, 2002, Houston, Texas.

1Conoco Inc., Ponca City, Oklahoma

2Conoco Inc., Houston, Texas

Summary

We demonstrate the difficulty with mapping a Lobo (Paleocene) hydrocarbon reservoir directly Previous HitfromNext Hit stacked Previous HitseismicNext Hit Previous HitdataNext Hit. A strong response in the stacked volume is ambiguous, indicating either a large impedance contrast or a contrast in Poisson’s ratio.

That is, stacking of reflection amplitudes over offset (or reflection angle) incorporates reflections Previous HitfromNext Hit impedance perturbations with those due to a change in Poisson’s ratio. Dipole sonic log Previous HitdataNext Hit indicate Poisson’s ratio, but not impedance, distinguishes this particular Lobo reservoir Previous HitfromNext Hit shale. The hydrocarbon reservoir impedance is similar to that of encasing shales. On the other hand, Poisson’s ratio decreases over 30% in the reservoir sand.

In this paper, we invert the prestack amplitudes of a Previous Hit3-DNext Hit Previous HitdataNext Hit volume to distinguish perturbations in impedance Previous HitfromNext Hit Poisson’s ratio perturbations. We may, therefore, recognize and map this Lobo reservoir as a decrease in Poisson’s ratio accompanied by little or no change in impedance.

 

uSummary

uFigure captions

uHistorical perspective

uLobo petrophysical evidence

uPrestack process

uLobo stack comparison

uConclusions

uAcknowledgements

uReferences

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

uSummary

uFigure captions

uHistorical perspective

uLobo petrophysical evidence

uPrestack process

uLobo stack comparison

uConclusions

uAcknowledgements

uReferences

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

uSummary

uFigure captions

uHistorical perspective

uLobo petrophysical evidence

uPrestack process

uLobo stack comparison

uConclusions

uAcknowledgements

uReferences

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

uSummary

uFigure captions

uHistorical perspective

uLobo petrophysical evidence

uPrestack process

uLobo stack comparison

uConclusions

uAcknowledgements

uReferences

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure Captions

Figure 1. P-wave impedance well log, coded according to log-derived lithology. The legend provides the code. Lobo hydrocarbon reservoirs are centered at four depths: 9560 ft, 9840 ft, 10200 ft, 10300 ft. Impedance does not distinguish Lobo hydrocarbon lithologies.

 

 

Figure 2. Poisson’s Ratio well log, coded according to log-derived lithology. The legend provides the code. Poisson’s Ratio discriminates Lobo hydrocarbons Previous HitfromNext Hit much of the nonpay section, particularly shale.

 

 

 

Click here to view sequence of Figures 1 and 2 (P-wave impedance and Poisson’s Ratio logs).

 

Figure 3. A time slice through the impedance perturbation cube Previous HitfromNext Hit Previous Hit3-DNext Hit prestack Previous HitinversionNext Hit. The well symbol shows the location of the well of Figure 1. This slice intersects the reservoir centered at a depth of 9560 ft. Impedance Previous HitfromNext Hit Previous HitinversionNext Hit does not reveal this Lobo reservoir, consistent with impedance log Previous HitdataNext Hit in Figure 1.

Figure 4. A time slice through the Poisson’s Ratio perturbation cube Previous HitfromNext Hit Previous Hit3-DNext Hit prestack Previous HitinversionNext Hit. The well symbol shows the location of the well of Figures 1 and 2. This slice intersects the reservoir centered at a depth of 9560 ft. Prestack Previous HitinversionNext Hit indicates an anomalous (large) decrease in Poisson’s Ratio for this Lobo reservoir. This is consistent with Poisson’s Ratio log Previous HitdataNext Hit in Figure 2.

 

Click here to view sequence of Figures 3 and 4 (slice--impedance and Poisson’s Ratio perturbation, respectively).

 

Figure 5. Color bar for Figures 3,4,6,7, and 8. Colors in Figures 3 and 4 indicate, respectively, the sign and magnitude of perturbations in impedance and Poisson’s Ratio. These perturbations are with respect to background values. Colors in Figure 6 signify the sign and magnitude of reflection amplitudes.

Figure 6. An inline slice through the Poisson’s Ratio perturbation cube Previous HitfromNext Hit Previous Hit3-DNext Hit prestack Previous HitinversionNext Hit.

 

Figure 7. An inline slice through the amplitude stack cube.

 

 

Figure 8. An inline slice through the impedance perturbation cube Previous HitfromNext Hit prestack Previous HitinversionNext Hit.

 

 

Click here to view sequence of Figures 6, 7, and 8 (slice--Poisson’s Ratio, amplitude, and impedance, respectively).

 

Historical Perspective

The upper Paleocene to Eocene Wilcox Lobo trend is a major low-permeability natural gas producer of the Texas Gulf Coast, already yielding approximately 4.5 TCF of gas. Both Previous HitstructuralNext Hit and stratigraphic complexity can complicate exploration and exploitation of the Lobo trend. Multiple episodes of faulting and erosion can make sand correlation difficult Previous HitfromNext Hit fault block to fault block.

Previous Lobo exploration tools consisted of open-hole logs and dipmeter Previous HitdataNext Hit combined with 2-D Previous HitseismicNext Hit Previous HitdataNext Hit. These techniques were useful for exploring large slump block features. Over time, the success of these techniques diminished as the size of potential targets decreased.

Continuous improvements in Previous Hit3-DNext Hit acquisition and processing over the last ten years have positively impacted Lobo exploration and development success. Current Previous Hit3-DNext Hit stack volumes resolve much smaller slump blocks. This improved Previous HitstructuralNext Hit definition helps identify acreage that yields superior drilling results.

Modern dipole sonic log measurements through the Lobo section point to Poisson’s ratio as a distinguishing reservoir property. Prestack imaging and Previous HitinversionNext Hit thus represent a logical next step in the evolution of Lobo exploration and exploitation technology.

In this paper we directly image a Lobo reservoir by inverting amplitudes before stack. A signature decrease in Poisson’s ratio tracks the reservoir across faulting.

 

Lobo Petrophysical Evidence

The well Previous HitdataNext Hit of Figures 1 and 2 make the case for prestack, rather than poststack, Previous HitinversionNext Hit in this area of the Lobo trend. Impedance alone fails to discriminate these Lobo hydrocarbon reservoirs Previous HitfromNext Hit surrounding shale. On the other hand, Poisson’s ratio decreases over 30% in the reservoir intervals.

 

Prestack Process

One can invert throughout the Previous Hit3-DNext Hit volume for perturbations in Poisson’s ratio, along with impedance perturbations. This Previous HitinversionNext Hit requires reflection amplitudes Previous HitfromNext Hit different angles, incident on the same image point in the volume.

Figures 3 and 4 give time slices of the resulting Previous HitinversionNext Hit output. These pictures show, respectively, an image of the perturbations in impedance and Poisson’s ratio. The Lobo reservoir at 9650 ft, for example, exhibits a large drop in Poisson’s ratio but no impedance signature. See Figure 5 for a color bar.

Though this prestack Previous HitinversionNext Hit result is consistent with log Previous HitdataNext Hit (Figures 1 and 2), it was not constrained by log Previous HitdataNext Hit. This Previous HitinversionNext Hit output derives entirely (Previous HitseismicNext Hit wavelet extraction excepted) Previous HitfromNext Hit prestack amplitude Previous HitdataNext Hit. We invert amplitudes via an expansion of the form

R(q ) =A + Bsin2q + Csin2q tan2q + K     (1)

Equation (1) expresses reflectivity R as a function of incidence angleq. One derives this equation following the approaches taken by Bortfeld (1961), and Aki and Richards (1980). Shuey (1985) presented a similar approximation.

Equation (1) also sets the goal of our entire prestack Previous HitdataNext Hit processing sequence: preserve this functional relationship between reflections recorded at different angles, while attenuating signals that do not conform to this reflectivity model. This is, of course, “easier said than done”. In the opinion of the first author, this processing goal encompasses most of the expertise required for robust prestack Previous HitinversionNext Hit.

Parameter A in equation (1) equates to a perturbation in impedance under the assumption of small perturbations.

Parameter B is the source of information on Poisson’s ratio. It depends in part on the product of perturbations in both impedance and Poisson’s ratio.

We truncated equation (1) before parameter C for the Previous HitinversionNext Hit of Figures 3 and 4. One often neglects this third term for incidence angles less than 25o, the maximum angle preserved through our prestack processing sequence. This term in the expansion is fourth order in q(for smallq ).

 

Lobo Stack Comparison

Equation (1) thus makes it clear that stacking of reflection amplitudes over angle incorporates reflections Previous HitfromNext Hit impedance perturbations with those due to a change in Poisson’s ratio. The A -term contributes the former, the B -term the latter. A strong response in the stacked volume is therefore ambiguous in terms of rock properties.

Figures 6, 7 and 8 taken together document this ambiguity for the Lobo section. The band of prominent reflections in the stack Previous HitdataNext Hit, just above 1.8 s, originates mainly Previous HitfromNext Hit impedance perturbations. The event marked by an arrow in these figures is an exception.

Previous HitInversionNext Hit before stack attributes this event to low Poisson’s ratio (Figure 6). This signature gives a direct image of the reservoir, mappable away Previous HitfromNext Hit well control and across fault terminations. On the other hand, this Lobo hydrocarbon reservoir is virtually transparent by way of impedance (Figure 8).

 

Conclusions

Multiple episodes of faulting and erosion in the Lobo trend can frustrate Previous HitseismicNext Hit correlation and mapping. Moreover, these Lobo reservoirs often produce a faint expression in the stack volume, especially compared to reflections Previous HitfromNext Hit large impedance contrasts.

Dipole sonic log Previous HitdataNext Hit reveal the petrophysical key to this problem. These Lobo reservoirs are reflective at non-zero incidence angles via a decrease in Poisson’s ratio. We may, therefore, directly image and map the reservoir by inverting prestack Previous HitdataNext Hit for perturbations in Poisson’s ratio. Previous HitInversionNext Hit for impedance shows little or no contrast at the reservoirs, as expected.

 

Acknowledgments

We thank Peter Lellis for hisencouragement and initiative to apply prestack Previous HitinversionNext Hit for his business unit. Richard Lunam suggested this Previous HitdataNext Hit set and directed much of the preprocessing for Previous HitinversionNext Hit. Bob Baumel developed much of the Previous HitinversionTop software. We also thank Conoco Inc. for permission to publish this paper.

 

References

Aki, K., and Richards, P.G., 1980, Quantitative seismology: Theory and methods: W.H. Freeman and Co.

Bortfeld, R., 1961, Approximation to the reflection and transmission coefficients of plane longitudinal and transverse waves: Geophys. Prosp., v. 9, 485-503.

Shuey, R.T., 1985, A simplification of the Zoeppritz equations: Geophysics, v. 50, p. 609-614.

 

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