Title
Quantitative prediction of injected CO2 at Sleipner using wave-equation based AVO
Author
Haffinger, P.
Jedari Eyvazi, F.
Steeghs, P.
Doulgeris, P.
Gisolf, D.
Verschuur, E.
Publication year
2018
Abstract
In the context of carbon capture and storage (CCS), quantitative estimation of injected CO2 is of vital importance to verify if the process occurs without any leakage. From a geophysical perspective this is challenging as a CO2 plume has a severe imprint on seismic data. While this makes delineation of the plume rather straightforward, for quantitative interpretation a technique is required that takes complex wave propagation, including multiple scattering and mode conversions into account. In this abstract a wave-equation based AVO technique is discussed and successfully demonstrated on a seismic dataset from the Sleipner site. The technique solves the exact wave-equation which means that tuning effects are properly modelled. The scheme directly inverts for compressibility and shear compliance as these parameters are more closely related to saturation than conventional impedances. From this the total amount of injected CO2 is calculated and found to be in good agreement with the known value at the time when the data was acquired. © 2018 European Association of Geoscientists and Engineers, EAGE. All rights reserved.
Subject
Carbon dioxide
Crack propagation
Digital storage
Geology
Seismology
Wave equations
Wave propagation
Carbon capture and storages (CCS)
Equation based
Mode conversions
Quantitative estimation
Quantitative interpretation
Quantitative prediction
Seismic datas
Shear compliance
Carbon capture
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http://resolver.tudelft.nl/uuid:9e0395f1-0856-4654-b732-c979b1653b63
TNO identifier
865916
Publisher
European Association of Geoscientists and Engineers, EAGE
ISBN
9789462822702
Source
5th CO2 Geological Storage Workshop, 5th CO2 Geological Storage Workshop, 21 November 2018 through 23 November 2018
Document type
conference paper