Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea

The Barents Sea is a prospective area in terms of hydrocarbon resources with high ratio of discovery wells. This study focuses on reservoir quality of two sandstone reservoirs of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex in the Norwegian Barents Sea. The stu...

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Bibliographic Details
Main Author: Zhang, Dechen
Format: Master Thesis
Language:English
Published: 2014
Subjects:
reservoir
quality
BarRock
petrophysics
rock
physics
AVO
modelling
Barents Sea
Loppa
Rho
Stø
Hammerfest
Hammerfest Basin
Online Access:http://hdl.handle.net/10852/42305
http://urn.nb.no/URN:NBN:no-46681
id ftoslouniv:oai:www.duo.uio.no:10852/42305
record_format openpolar
institution Open Polar
collection Universitet i Oslo: Digitale utgivelser ved UiO (DUO)
op_collection_id ftoslouniv
language English
topic reservoir
quality
BarRock
petrophysics
rock
physics
AVO
modelling
spellingShingle reservoir
quality
BarRock
petrophysics
rock
physics
AVO
modelling
Zhang, Dechen
Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea
topic_facet reservoir
quality
BarRock
petrophysics
rock
physics
AVO
modelling
description The Barents Sea is a prospective area in terms of hydrocarbon resources with high ratio of discovery wells. This study focuses on reservoir quality of two sandstone reservoirs of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex in the Norwegian Barents Sea. The study methods include petrophysics analysis, rock physics diagnostics and AVO modelling. Seven exploration wells from the study area are analysed to investigate the reservoir quality of two target reservoirs. The studied reservoir sandstones are buried at different depth levels from approximately 1400 m to 3300 m (RKB). Therefore, this database provides a perfect profile for sandstone compaction and diagenetic studies. A comparison of Vp-depth trends in studied wells and published Vp-depth trends for normally subsided basins shows that the Vp in the study area are much higher than expected. The calculated average porosity values of the reservoirs are much lower than published porosity-depth trends. Regional uplift and erosion is attributed as the main reason for these anomalous values. The estimated average uplift in the study area is about 900 m. The exhumation decrease to the north-west direction. After estimation of uplift, the present depth is corrected to a maximum burial depth. New depth data are subsequently used to calculate maximum burial temperatures for the reservoirs. The maximum temperatures show that the sediments have experienced much higher thermal exposures than what is interpolated from bottom hole temperatures. All the reservoirs in the studied wells are within the zone of chemical compaction. It is clear from petrophysical analysis that the reservoir quality of the Knurr Formation is poorer compared to the Stø Formation. The Knurr Formation is deposited in a submarine fan system while the Stø Formation is deposited in a coastal environment. Different sedimentary environments result in different reservoir parameters, like net-to-gross ratio, shale volume and porosity. Rock physics templates work well for estimating quartz cement content and for distinguishing different lithologies and pore fluids. Even the shallowest buried sandstones (around 1200 meters below sea floor) in well 7119/12-2 contain cements between the grains according to rock physics diagnostic results. This is also confirmed by published literatures. Secondary porosity is also common in the studied wells. A clear trend of rock properties with increasing depth is observed in all of the rock physics templates used. Lamda-Rho versus Mu-Rho cross plot works better than Vp/Vs versus IP cross plot for discriminating the lithology and fluid in the studied wells. Due to the complex compaction and diagenetic history, the shear wave velocity measured in well 7119/12-4 is abnormally high. These high shear wave velocities result false gas effect in rock physics templates (e.g. Vp/Vs versus IP and LMR). The AVO modelling results agree reasonably well with the classical AVO theory. The gas-bearing data points deviate from the background trend at both the top and bottom interfaces of the reservoirs. An impedance inversion with increasing depth is observed in the AVO modelling for the Stø Formation sandstones. With increasing depth, the soft sandstones turn into hard sandstones compared to the overlying shale. The AVO modelling results are sensitive to many factors, like water saturation, wavelet and block size. The measured Vs values in well 7119/12-4 also result false gas effect in AVO modelling.
format Master Thesis
author Zhang, Dechen
author_facet Zhang, Dechen
author_sort Zhang, Dechen
title Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea
title_short Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea
title_full Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea
title_fullStr Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea
title_full_unstemmed Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea
title_sort imaging reservoir quality of knurr and stø formations in the hammerfest basin and ringvassøy-loppa fault complex, norwegian barents sea
publishDate 2014
url http://hdl.handle.net/10852/42305
http://urn.nb.no/URN:NBN:no-46681
long_lat ENVELOPE(22.351,22.351,70.240,70.240)
ENVELOPE(-63.000,-63.000,-64.300,-64.300)
ENVELOPE(15.124,15.124,69.019,69.019)
geographic Barents Sea
Loppa
Rho
Stø
geographic_facet Barents Sea
Loppa
Rho
Stø
genre Barents Sea
Hammerfest
Hammerfest Basin
Loppa
genre_facet Barents Sea
Hammerfest
Hammerfest Basin
Loppa
op_relation http://urn.nb.no/URN:NBN:no-46681
Zhang, Dechen. Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea. Master thesis, University of Oslo, 2014
http://hdl.handle.net/10852/42305
URN:NBN:no-46681
Fulltext https://www.duo.uio.no/bitstream/handle/10852/42305/1/MSc-thesis_Dechen-Zhang-2014.pdf
_version_ 1766370300854796288
spelling ftoslouniv:oai:www.duo.uio.no:10852/42305 2023-05-15T15:38:54+02:00 Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea Zhang, Dechen 2014 http://hdl.handle.net/10852/42305 http://urn.nb.no/URN:NBN:no-46681 eng eng http://urn.nb.no/URN:NBN:no-46681 Zhang, Dechen. Imaging reservoir quality of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex, Norwegian Barents Sea. Master thesis, University of Oslo, 2014 http://hdl.handle.net/10852/42305 URN:NBN:no-46681 Fulltext https://www.duo.uio.no/bitstream/handle/10852/42305/1/MSc-thesis_Dechen-Zhang-2014.pdf reservoir quality BarRock petrophysics rock physics AVO modelling Master thesis Masteroppgave 2014 ftoslouniv 2020-06-21T08:47:47Z The Barents Sea is a prospective area in terms of hydrocarbon resources with high ratio of discovery wells. This study focuses on reservoir quality of two sandstone reservoirs of Knurr and Stø Formations in the Hammerfest Basin and Ringvassøy-Loppa Fault Complex in the Norwegian Barents Sea. The study methods include petrophysics analysis, rock physics diagnostics and AVO modelling. Seven exploration wells from the study area are analysed to investigate the reservoir quality of two target reservoirs. The studied reservoir sandstones are buried at different depth levels from approximately 1400 m to 3300 m (RKB). Therefore, this database provides a perfect profile for sandstone compaction and diagenetic studies. A comparison of Vp-depth trends in studied wells and published Vp-depth trends for normally subsided basins shows that the Vp in the study area are much higher than expected. The calculated average porosity values of the reservoirs are much lower than published porosity-depth trends. Regional uplift and erosion is attributed as the main reason for these anomalous values. The estimated average uplift in the study area is about 900 m. The exhumation decrease to the north-west direction. After estimation of uplift, the present depth is corrected to a maximum burial depth. New depth data are subsequently used to calculate maximum burial temperatures for the reservoirs. The maximum temperatures show that the sediments have experienced much higher thermal exposures than what is interpolated from bottom hole temperatures. All the reservoirs in the studied wells are within the zone of chemical compaction. It is clear from petrophysical analysis that the reservoir quality of the Knurr Formation is poorer compared to the Stø Formation. The Knurr Formation is deposited in a submarine fan system while the Stø Formation is deposited in a coastal environment. Different sedimentary environments result in different reservoir parameters, like net-to-gross ratio, shale volume and porosity. Rock physics templates work well for estimating quartz cement content and for distinguishing different lithologies and pore fluids. Even the shallowest buried sandstones (around 1200 meters below sea floor) in well 7119/12-2 contain cements between the grains according to rock physics diagnostic results. This is also confirmed by published literatures. Secondary porosity is also common in the studied wells. A clear trend of rock properties with increasing depth is observed in all of the rock physics templates used. Lamda-Rho versus Mu-Rho cross plot works better than Vp/Vs versus IP cross plot for discriminating the lithology and fluid in the studied wells. Due to the complex compaction and diagenetic history, the shear wave velocity measured in well 7119/12-4 is abnormally high. These high shear wave velocities result false gas effect in rock physics templates (e.g. Vp/Vs versus IP and LMR). The AVO modelling results agree reasonably well with the classical AVO theory. The gas-bearing data points deviate from the background trend at both the top and bottom interfaces of the reservoirs. An impedance inversion with increasing depth is observed in the AVO modelling for the Stø Formation sandstones. With increasing depth, the soft sandstones turn into hard sandstones compared to the overlying shale. The AVO modelling results are sensitive to many factors, like water saturation, wavelet and block size. The measured Vs values in well 7119/12-4 also result false gas effect in AVO modelling. Master Thesis Barents Sea Hammerfest Hammerfest Basin Loppa Universitet i Oslo: Digitale utgivelser ved UiO (DUO) Barents Sea Loppa ENVELOPE(22.351,22.351,70.240,70.240) Rho ENVELOPE(-63.000,-63.000,-64.300,-64.300) Stø ENVELOPE(15.124,15.124,69.019,69.019)

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