Monitoring CO<sub>2</sub> saturation using time‐lapse amplitude versus offset analysis of 3D seismic data from the Ketzin CO<sub>2</sub> storage pilot site, Germany

Ivandic, Monika; Bergmann, Peter G.; Kummerow, J.; Huang, Fei; Juhlin, Christopher; Lueth, S.

doi:10.1111/1365-2478.12666

Cited by 6 publications

(4 citation statements)

References 43 publications

(115 reference statements)

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“…Time-lapse seismic has become increasingly important to monitor fluid flows and geomechanical changes in subsurface reservoirs, such as observing pressure and saturation changes (Johnston et al, 1998;Landrø, 2001;Dadashpour et al, 2007), monitoring CO 2 storage sites (Chadwick et al, 2010;Pevzner et al, 2011;Ivandic et al, 2018) and assessing compaction and subsidence (Barkved and Kristiansen, 2005;Hatchell and Bourne, 2005). Typically, these studies compare an initial baseline study followed by one or more monitor studies.…”

Section: Introductionmentioning

confidence: 99%

Time-lapse applications of the Marchenko method on the Troll field

IJsseldijk¹,

Brackenhoff²,

Thorbecke³

et al. 2023

Preprint

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The data-driven Marchenko method is able to redatum wavefields to arbitrary locations in the subsurface, and can, therefore, be used to isolate zones of specific interest. This creates a new reflection response of the target zone without interference from over-or underburden reflectors. Consequently, the method is well suited to obtain a clear response of a subsurface reservoir, which can be advantageous in time-lapse studies. The clean isolated responses of a baseline and monitor survey can be more effectively compared, hence the retrieval of time-lapse characteristics is improved. This research aims to apply Marchenko-based isolation to a time-lapse marine dataset of the Troll field in Norway in order to acquire an unobstructed image of the primary reflections, and retrieve small time-lapse traveltime difference in the reservoir. It is found that the method not only isolates the primary reflections but can also recover internal multiples outside the recording time. Both the primaries and the multiples can then be utilised to find time-lapse traveltime differences. More accurate ways of time-lapse monitoring will allow for a better understanding of dynamic processes in the subsurface, such as observing saturation and pressure changes in a reservoir or monitoring underground storage of hydrogen and CO 2 .

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Section: Introductionmentioning

confidence: 99%

Time-lapse applications of the Marchenko method on the Troll field

IJsseldijk¹,

Brackenhoff²,

Thorbecke³

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…Time‐lapse seismic has become increasingly important to monitor fluid flows and geomechanical changes in subsurface reservoirs, such as observing pressure and saturation changes (Dadashpour et al., 2007; Johnston et al., 1998; Landrø, 2001), monitoring CO 2 storage sites (Chadwick et al., 2010; Ivandic et al., 2018; Pevzner et al., 2011) and assessing compaction and subsidence (Barkved & Kristiansen, 2005; Hatchell & Bourne, 2005). Typically, these studies compare an initial baseline study followed by one or more monitor studies.…”

Section: Introductionmentioning

confidence: 99%

Time‐lapse applications of the Marchenko method on the Troll field

van IJsseldijk,

Brackenhoff,

Thorbecke

et al. 2023

Geophysical Prospecting

View full text Add to dashboard Cite

The data‐driven Marchenko method is able to redatum wavefields to arbitrary locations in the subsurface, and can, therefore, be used to isolate zones of specific interest. This creates a new reflection response of the target zone without interference from over‐ or underburden reflectors. Consequently, the method is well suited to obtain a clear response of a subsurface reservoir, which can be advantageous in time‐lapse studies. The isolated responses of a baseline and monitor survey can be more effectively compared; hence, the retrieval of time‐lapse characteristics is improved. This research aims to apply Marchenko‐based isolation to a time‐lapse marine data set of the Troll field in Norway in order to acquire an unobstructed image of the primary reflections and retrieve small time‐lapse traveltime difference in the reservoir. It is found that the method not only isolates the primary reflections but can also estimate internal multiples outside the recording time. Both the primaries and the multiples can then be utilized to find time‐lapse traveltime differences. More accurate ways of time‐lapse monitoring will allow for a better understanding of dynamic processes in the subsurface, such as observing saturation and pressure changes in a reservoir or monitoring underground storage of hydrogen and CO2.

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“…Carbon capture, utilization and storage encompasses technologies to capture carbon dioxide (CO 2 ) from the atmosphere or from industrial emission sites, and to subsequent recycle the captured CO 2 for exploring or determining safe and permanent storage options (Pacala & Socolow, 2004). A relatively mature option is injecting nearly pure CO 2 streams into geologic formations for long‐term storage (Pires et al., 2011) which has demonstrated its effectiveness in a range of injection projects worldwide, including the Cranfield oilfield in the United States (Hovorka et al., 2013), the Jilin Oilfield in China (Ren et al., 2016), the Sleipner field offshore Norway (Chadwick & Noy, 2015), the Ketzin pilot site in Germany (Ivandic et al., 2018), the In Salah field in Algeria (White et al., 2014), potential sites in Korea (Kim, 2013), and the Aquistore in Saskatchewan, Canada (Emberley et al., 2004; Stork, Nixon, et al., 2018). Timely detection of subsurface structural changes resulting from stresses triggered by CO 2 injection is critical to prevent or mitigate potential containment failures and to demonstrate the security of the CO 2 within the storage complex (Gholami et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

Monitoring CO₂ Injection at the CaMI Field Research Station Using Microseismic Noise Sources

Lawton

et al. 2022

JGR Solid Earth

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Carbon capture, utilization and storage encompasses technologies to capture carbon dioxide (CO 2 ) from the atmosphere or from industrial emission sites, and to subsequent recycle the captured CO 2 for exploring or determining safe and permanent storage options (Pacala & Socolow, 2004). A relatively mature option is injecting nearly pure CO 2 streams into geologic formations for long-term storage (Pires et al., 2011) which has demonstrated its effectiveness in a range of injection projects worldwide, including the Cranfield oilfield in the United

show abstract

Monitoring CO₂ saturation using time‐lapse amplitude versus offset analysis of 3D seismic data from the Ketzin CO₂ storage pilot site, Germany

Cited by 6 publications

References 43 publications

Time-lapse applications of the Marchenko method on the Troll field

Time-lapse applications of the Marchenko method on the Troll field

Time‐lapse applications of the Marchenko method on the Troll field

Monitoring CO₂ Injection at the CaMI Field Research Station Using Microseismic Noise Sources

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Monitoring CO2 saturation using time‐lapse amplitude versus offset analysis of 3D seismic data from the Ketzin CO2 storage pilot site, Germany

Cited by 6 publications

References 43 publications

Time-lapse applications of the Marchenko method on the Troll field

Time-lapse applications of the Marchenko method on the Troll field

Time‐lapse applications of the Marchenko method on the Troll field

Monitoring CO2 Injection at the CaMI Field Research Station Using Microseismic Noise Sources

Contact Info

Product

Resources

About

Monitoring CO₂ saturation using time‐lapse amplitude versus offset analysis of 3D seismic data from the Ketzin CO₂ storage pilot site, Germany

Monitoring CO₂ Injection at the CaMI Field Research Station Using Microseismic Noise Sources