In-Reservoir Waveform Retrieval for Monitoring at Groningen—Seismic Interferometry with Active and Passive Deep Borehole Data

Muhammad F. Akbar; Ivan Vasconcelos; Hanneke Paulssen; Wen Zhou

doi:10.3390/rs13152928

In-Reservoir Waveform Retrieval for Monitoring at Groningen—Seismic Interferometry with Active and Passive Deep Borehole Data

Muhammad F. Akbar, Ivan Vasconcelos^*, Hanneke Paulssen, Wen Zhou

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The Groningen gas field in the Netherlands is an ideal test bed for in-situ reservoir monitoring techniques because of the availability of both active and passive in-reservoir seismic data. In this study, we use deconvolution interferometry to estimate the reflection and transmission response using active and passive borehole data within the reservoir at ∼3-km depth and separate up- and downgoing P- and S-wave fields by f-k filtering. We validate the results using synthetic data of a 1D elastic model built from sonic logs recorded in the well. The estimated full-waveform reflection response for a virtual source at the top geophone is consistent with the synthetic response. For the virtual source at the bottom geophone, the reflection response appears to be phase delayed, though its arrivals are consistent with the local subsurface geology. Similarly, the first-order estimated local transmission response successfully approximates that of the P-wave velocity in the reservoir. The study shows that reliable subsurface information can be obtained from borehole interferometry without detailed knowledge of the medium parameters. In addition, the method could be used for passive reservoir monitoring to detect velocity, attenuation, and/or interface time-lapse variations.

Original language	English
Article number	2928
Number of pages	20
Journal	Remote Sensing
Volume	13
Issue number	15
DOIs	https://doi.org/10.3390/rs13152928
Publication status	Published - 1 Aug 2021

Bibliographical note

Funding Information:
M.F.A. thanks the Indonesia Endowment Fund for Education, abbreviated as LPDP, from the Indonesian Ministry of Finance for sponsoring his MSc study. We thank Kees Wapenaar (TU Delft) for providing the 1D elastic modeling code used to generate our synthetic data. We are very grateful to the NAM for kindly providing the velocity models, borehole, and well-log data. M.F.A. conducted this research as part of completing his MSc in Earth Sciences at Utrecht University.

Funding Information:
Funding: M.F.A. thanks the Indonesia Endowment Fund for Education, abbreviated as LPDP, from the Indonesian Ministry of Finance for sponsoring his MSc study.

Publisher Copyright:
© 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Keywords

Borehole
Deconvolution
Groningen
Reflection response
Seismic interferometry
Transmission response
Up-down separation

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10.3390/rs13152928Licence: CC BY

remotesensing-13-02928-v2Final published version, 8.51 MBLicence: CC BY

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title = "In-Reservoir Waveform Retrieval for Monitoring at Groningen—Seismic Interferometry with Active and Passive Deep Borehole Data",

abstract = "The Groningen gas field in the Netherlands is an ideal test bed for in-situ reservoir monitoring techniques because of the availability of both active and passive in-reservoir seismic data. In this study, we use deconvolution interferometry to estimate the reflection and transmission response using active and passive borehole data within the reservoir at ∼3-km depth and separate up- and downgoing P- and S-wave fields by f-k filtering. We validate the results using synthetic data of a 1D elastic model built from sonic logs recorded in the well. The estimated full-waveform reflection response for a virtual source at the top geophone is consistent with the synthetic response. For the virtual source at the bottom geophone, the reflection response appears to be phase delayed, though its arrivals are consistent with the local subsurface geology. Similarly, the first-order estimated local transmission response successfully approximates that of the P-wave velocity in the reservoir. The study shows that reliable subsurface information can be obtained from borehole interferometry without detailed knowledge of the medium parameters. In addition, the method could be used for passive reservoir monitoring to detect velocity, attenuation, and/or interface time-lapse variations. ",

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author = "Akbar, {Muhammad F.} and Ivan Vasconcelos and Hanneke Paulssen and Wen Zhou",

note = "Funding Information: M.F.A. thanks the Indonesia Endowment Fund for Education, abbreviated as LPDP, from the Indonesian Ministry of Finance for sponsoring his MSc study. We thank Kees Wapenaar (TU Delft) for providing the 1D elastic modeling code used to generate our synthetic data. We are very grateful to the NAM for kindly providing the velocity models, borehole, and well-log data. M.F.A. conducted this research as part of completing his MSc in Earth Sciences at Utrecht University. Funding Information: Funding: M.F.A. thanks the Indonesia Endowment Fund for Education, abbreviated as LPDP, from the Indonesian Ministry of Finance for sponsoring his MSc study. Publisher Copyright: {\textcopyright} 2021 by the authors. Licensee MDPI, Basel, Switzerland.",

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N1 - Funding Information: M.F.A. thanks the Indonesia Endowment Fund for Education, abbreviated as LPDP, from the Indonesian Ministry of Finance for sponsoring his MSc study. We thank Kees Wapenaar (TU Delft) for providing the 1D elastic modeling code used to generate our synthetic data. We are very grateful to the NAM for kindly providing the velocity models, borehole, and well-log data. M.F.A. conducted this research as part of completing his MSc in Earth Sciences at Utrecht University. Funding Information: Funding: M.F.A. thanks the Indonesia Endowment Fund for Education, abbreviated as LPDP, from the Indonesian Ministry of Finance for sponsoring his MSc study. Publisher Copyright: © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

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N2 - The Groningen gas field in the Netherlands is an ideal test bed for in-situ reservoir monitoring techniques because of the availability of both active and passive in-reservoir seismic data. In this study, we use deconvolution interferometry to estimate the reflection and transmission response using active and passive borehole data within the reservoir at ∼3-km depth and separate up- and downgoing P- and S-wave fields by f-k filtering. We validate the results using synthetic data of a 1D elastic model built from sonic logs recorded in the well. The estimated full-waveform reflection response for a virtual source at the top geophone is consistent with the synthetic response. For the virtual source at the bottom geophone, the reflection response appears to be phase delayed, though its arrivals are consistent with the local subsurface geology. Similarly, the first-order estimated local transmission response successfully approximates that of the P-wave velocity in the reservoir. The study shows that reliable subsurface information can be obtained from borehole interferometry without detailed knowledge of the medium parameters. In addition, the method could be used for passive reservoir monitoring to detect velocity, attenuation, and/or interface time-lapse variations.

AB - The Groningen gas field in the Netherlands is an ideal test bed for in-situ reservoir monitoring techniques because of the availability of both active and passive in-reservoir seismic data. In this study, we use deconvolution interferometry to estimate the reflection and transmission response using active and passive borehole data within the reservoir at ∼3-km depth and separate up- and downgoing P- and S-wave fields by f-k filtering. We validate the results using synthetic data of a 1D elastic model built from sonic logs recorded in the well. The estimated full-waveform reflection response for a virtual source at the top geophone is consistent with the synthetic response. For the virtual source at the bottom geophone, the reflection response appears to be phase delayed, though its arrivals are consistent with the local subsurface geology. Similarly, the first-order estimated local transmission response successfully approximates that of the P-wave velocity in the reservoir. The study shows that reliable subsurface information can be obtained from borehole interferometry without detailed knowledge of the medium parameters. In addition, the method could be used for passive reservoir monitoring to detect velocity, attenuation, and/or interface time-lapse variations.

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KW - Reflection response

KW - Seismic interferometry

KW - Transmission response

KW - Up-down separation

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ER -

In-Reservoir Waveform Retrieval for Monitoring at Groningen—Seismic Interferometry with Active and Passive Deep Borehole Data

Abstract

Bibliographical note

Keywords

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