Volumetric bounds on subsurface fluid substitution using 4D seismic time shifts with an application at Sleipner, North Sea

Bergmann, Peter G.; Chadwick, Andrew

doi:10.1190/geo2014-0591.1

Cited by 15 publications

(15 citation statements)

References 26 publications

(30 reference statements)

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“…On the 2006 vintage, they get saturations ranging from 20% (deeper layers) to 90% (870 m deep layer), but P-wave velocities are very low, approximately 1200 m∕s. Boait et al (2012) and Bergmann and Chadwick (2015), using volumetric estimations, derive similar conclusions about the fluid distribution; i.e., the saturation is most likely uniform in high saturation zones and following patchy mixing laws elsewhere. Golding and Huppert (2011) agree with Queißer and Singh (2013) that saturation is probably greater than 30%.…”

Section: Discussionmentioning

confidence: 71%

“…Mohapatra et al (2012) conduct laboratory experiments on partially saturated sandstone (gas-brine, oil-brine, and CO 2 -brine) and show that the P-wave velocities and impedances are in good agreement with laboratory measurements except for liquid CO 2 flooding. Usually, Gassmann fluid substitution (Gassmann, 1951) combined with effective fluid bulk modulus (calculated by averages) are used for estimation of saturation from seismic velocities or time shifts (Bergmann and Chadwick, 2015). Otherwise, the Gassmann equation is a zero-frequency approximation and the computation of the effective fluid bulk modulus strongly depends on saturation distribution.…”

Section: Introductionmentioning

confidence: 99%

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Quantitative seismic characterization of CO₂ at the Sleipner storage site, North Sea

et al. 2017

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Reliable quantification of carbon dioxide (CO 2 ) properties and saturation is crucial in the monitoring of CO 2 underground storage projects. We have focused on quantitative seismic characterization of CO 2 at the Sleipner storage pilot site. We evaluate a methodology combining high-resolution seismic waveform tomography, with uncertainty quantification and rock physics inversion. We use full-waveform inversion (FWI) to provide highresolution estimates of P-wave velocity V P and perform an evaluation of the reliability of the derived model based on posterior covariance matrix analysis. To get realistic estimates of CO 2 saturation, we implement advanced rock physics models taking into account effective fluid phase theory and patchy saturation. We determine through sensitivity tests that the estimation of CO 2 saturation is possible even when using only the P-wave velocity as input. After a characterization of rock frame properties based on log data prior to the CO 2 injection at Sleipner, we apply our two-step methodology. The FWI result provides clear indications of the injected CO 2 plume being observed as low-velocity zones corresponding to thin CO 2 filled layers. Several tests, varying the rock physics model and CO 2 properties, are then performed to estimate CO 2 saturation. The results suggest saturations reaching 30%-35% in the thin sand layers and up to 75% when patchy mixing is considered. We have carried out a joint estimation of saturation with distribution type and, even if the inversion is not wellconstrained due to limited input data, we conclude that the CO 2 has an intermediate pattern between uniform and patchy mixing, which leads to saturation levels of approximately 25% AE 15%. It is worth noting that the 2D section used in this work is located 533 m east of the injection point. We also conclude that the joint estimation of CO 2 properties with saturation is not crucial and consequently that knowing the pressure and temperature state of the reservoir does not prevent reliable estimation of CO 2 saturation.

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Section: Discussionmentioning

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Quantitative seismic characterization of CO₂ at the Sleipner storage site, North Sea

et al. 2017

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“…() are affected by considerable uncertainties related to the choices of input parameters (Ivanova et al . ; Bergmann and Chadwick ; Ivandic et al . ).…”

Section: Quantitative Interpretation Of the Time‐lapse Seismic Signaturementioning

confidence: 99%

“…In order to compute the range of possible CO 2 masses in the layer, Bergmann and Chadwick () proposed the generalised velocity–saturation relationship

v (s_{2}) = v_{1} + (1 - \frac{p (1 - S_{normalC O_{2}})}{p + S_{C {normalO}_{2}}}) Δ v,

that is parameterised by the patchiness parameter p and the velocity change ∆v . The velocity change is given by the difference of the velocities for full CO 2 saturation, v 2 = v

(S_{normalC O_{2}} = 1)

, and full brine saturation, i.e., ∆v = v 2 – v 1 .…”

Section: Volumetric Bounds Using Non‐patchy Saturation Modelsmentioning

confidence: 99%

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The first post‐injection seismic monitor survey at the Ketzin pilot CO₂ storage site: results from time‐lapse analysis

Huang

Bergmann

Juhlin

et al. 2017

Geophysical Prospecting

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The injection of CO2 at the Ketzin pilot CO2 storage site started in June 2008 and ended in August 2013. During the 62 months of injection, a total amount of about 67 kt of CO2 was injected into a saline aquifer. A third repeat three‐dimensional seismic survey, serving as the first post‐injection survey, was acquired in 2015, aiming to investigate the recent movement of the injected CO2. Consistent with the previous two time‐lapse surveys, a predominantly west–northwest migration of the gaseous CO2 plume in the up‐dip direction within the reservoir is inferred in this first post‐injection survey. No systematic anomalies are detected through the reservoir overburden. The extent of the CO2 plume west of the injection site is almost identical to that found in the 2012 second repeat survey (after injection of 61 kt); however, there is a significant decrease in its size east of the injection site. Assessment of the CO2 plume distribution suggests that the decrease in the size of the anomaly may be due to multiple factors, such as limited vertical resolution, CO2 dissolution, and CO2 migration into thin layers, in addition to the effects of ambient noise. Four‐dimensional seismic modelling based on dynamic flow simulations indicates that a dynamic balance between the newly injected CO2 after the second repeat survey and the CO2 migrating into thin layers and being dissolved was reached by the time of the first post‐injection survey. In view of the significant uncertainties in CO2 mass estimation, both patchy and non‐patchy saturation models for the Ketzin site were taken into consideration.

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Toward Quantitative CO ₂ Monitoring at Sleipner, Norway

Romdhane

Dupuy

Querendez

et al. 2022

Geophysical Monitoring for Geologic Carbon Storage

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Volumetric bounds on subsurface fluid substitution using 4D seismic time shifts with an application at Sleipner, North Sea

Cited by 15 publications

References 26 publications

Quantitative seismic characterization of CO₂ at the Sleipner storage site, North Sea

Quantitative seismic characterization of CO₂ at the Sleipner storage site, North Sea

The first post‐injection seismic monitor survey at the Ketzin pilot CO₂ storage site: results from time‐lapse analysis

Toward Quantitative CO ₂ Monitoring at Sleipner, Norway

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Volumetric bounds on subsurface fluid substitution using 4D seismic time shifts with an application at Sleipner, North Sea

Cited by 15 publications

References 26 publications

Quantitative seismic characterization of CO2 at the Sleipner storage site, North Sea

Quantitative seismic characterization of CO2 at the Sleipner storage site, North Sea

The first post‐injection seismic monitor survey at the Ketzin pilot CO2 storage site: results from time‐lapse analysis

Toward Quantitative CO 2 Monitoring at Sleipner, Norway

Contact Info

Product

Resources

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Quantitative seismic characterization of CO₂ at the Sleipner storage site, North Sea

Quantitative seismic characterization of CO₂ at the Sleipner storage site, North Sea

The first post‐injection seismic monitor survey at the Ketzin pilot CO₂ storage site: results from time‐lapse analysis

Toward Quantitative CO ₂ Monitoring at Sleipner, Norway