Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea
Time-lapse 3D seismic which geoscientists often abbreviate to 4D seismic has the potential to monitor changes especially in pore pressure, hydrocarbon and brine saturation in a reservoir due to production or water/gas injection. This is achieved by repeating 3D seismic surveys over some known time i...
| Main Author: | |
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| Format: | Master Thesis |
| Language: | English |
| Published: |
The University of Bergen
2014
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| Subjects: | |
| Online Access: | https://hdl.handle.net/1956/8330 |
| _version_ | 1821667109401264128 |
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| author | Kabanda, Albert |
| author_facet | Kabanda, Albert |
| author_sort | Kabanda, Albert |
| collection | University of Bergen: Bergen Open Research Archive (BORA-UiB) |
| description | Time-lapse 3D seismic which geoscientists often abbreviate to 4D seismic has the potential to monitor changes especially in pore pressure, hydrocarbon and brine saturation in a reservoir due to production or water/gas injection. This is achieved by repeating 3D seismic surveys over some known time interval and the difference between different parameters can be analyzed. This study presents the use of rock physics templates (RPTs) in both reservoir characterization and 4D seismic reservoir monitoring. 4D well-log effect modeling and RPT analysis were used to investigate the power of RPTs towards reservoir characterization and monitoring on the Yttergryta field. Gassmann's fluid substitution modeling was applied on real well-log data to model 4D well-log effects, which included compressional and shear velocity logs, density logs to produce synthetic well-logs representing the reservoir at 25%, 50%, 75% and 100% fluid saturations of brine and gas. Three cases were considered; (1) fluid saturation changes (gas-brine) in Garn formation, (2) change of the gas-water contact in the Ile formation and (3) fluid saturation changes (gas-oil) in the whole reservoir interval from top Garn to base Ile. The Not formation which is between Garn and Ile was left out during fluid substitution. Generally the average Vp/Vs for brine saturated reservoir (around 1.9) was observed to be higher than that of gas (around 1.55-1.72) saturated reservoir cases. The original and fluid substituted logs were used to calculate amplitude versus angle (AVA) synthetics for all the three cases mentioned above using Zoeppritz equations for near angle (5) and far angle (30) degrees, using a zero phase Ricker wavelet of assumed dominant frequency 25 Hz. Seismic amplitude variation on the computed AVA prestack synthetics shown as gathers was found to be successful at showing brine substitution effects. To further appreciate these fluid saturation changes, the differences between the original (base) and the fluid substituted (monitor) AVA synthetics were ... |
| format | Master Thesis |
| genre | Norwegian Sea |
| genre_facet | Norwegian Sea |
| geographic | Norwegian Sea Garn |
| geographic_facet | Norwegian Sea Garn |
| id | ftunivbergen:oai:bora.uib.no:1956/8330 |
| institution | Open Polar |
| language | English |
| long_lat | ENVELOPE(160.425,160.425,66.302,66.302) |
| op_collection_id | ftunivbergen |
| op_relation | https://hdl.handle.net/1956/8330 |
| op_rights | Copyright the author. All rights reserved |
| publishDate | 2014 |
| publisher | The University of Bergen |
| record_format | openpolar |
| spelling | ftunivbergen:oai:bora.uib.no:1956/8330 2025-01-16T23:59:00+00:00 Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea Kabanda, Albert 2014-06-02 8383282 bytes application/pdf https://hdl.handle.net/1956/8330 eng eng The University of Bergen https://hdl.handle.net/1956/8330 Copyright the author. All rights reserved 756199 Master thesis 2014 ftunivbergen 2023-03-14T17:39:33Z Time-lapse 3D seismic which geoscientists often abbreviate to 4D seismic has the potential to monitor changes especially in pore pressure, hydrocarbon and brine saturation in a reservoir due to production or water/gas injection. This is achieved by repeating 3D seismic surveys over some known time interval and the difference between different parameters can be analyzed. This study presents the use of rock physics templates (RPTs) in both reservoir characterization and 4D seismic reservoir monitoring. 4D well-log effect modeling and RPT analysis were used to investigate the power of RPTs towards reservoir characterization and monitoring on the Yttergryta field. Gassmann's fluid substitution modeling was applied on real well-log data to model 4D well-log effects, which included compressional and shear velocity logs, density logs to produce synthetic well-logs representing the reservoir at 25%, 50%, 75% and 100% fluid saturations of brine and gas. Three cases were considered; (1) fluid saturation changes (gas-brine) in Garn formation, (2) change of the gas-water contact in the Ile formation and (3) fluid saturation changes (gas-oil) in the whole reservoir interval from top Garn to base Ile. The Not formation which is between Garn and Ile was left out during fluid substitution. Generally the average Vp/Vs for brine saturated reservoir (around 1.9) was observed to be higher than that of gas (around 1.55-1.72) saturated reservoir cases. The original and fluid substituted logs were used to calculate amplitude versus angle (AVA) synthetics for all the three cases mentioned above using Zoeppritz equations for near angle (5) and far angle (30) degrees, using a zero phase Ricker wavelet of assumed dominant frequency 25 Hz. Seismic amplitude variation on the computed AVA prestack synthetics shown as gathers was found to be successful at showing brine substitution effects. To further appreciate these fluid saturation changes, the differences between the original (base) and the fluid substituted (monitor) AVA synthetics were ... Master Thesis Norwegian Sea University of Bergen: Bergen Open Research Archive (BORA-UiB) Norwegian Sea Garn ENVELOPE(160.425,160.425,66.302,66.302) |
| spellingShingle | 756199 Kabanda, Albert Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea |
| title | Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea |
| title_full | Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea |
| title_fullStr | Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea |
| title_full_unstemmed | Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea |
| title_short | Rock Physics Templates for 4D Seismic Reservoir Monitoring: A case study from Yttergryta field in the Norwegian Sea |
| title_sort | rock physics templates for 4d seismic reservoir monitoring: a case study from yttergryta field in the norwegian sea |
| topic | 756199 |
| topic_facet | 756199 |
| url | https://hdl.handle.net/1956/8330 |