Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries

Exploration in the Barents Sea has shown to be difficult, due to the regional tectonic history to the area. Multiple uplift events, faulting and erosion make the well log data behave differently than expected in other areas on the NCS. This study focuses on the reservoirs in PermianTriassic- Jurassi...

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Bibliographic Details
Main Author: Viga, Odd Fossaa
Format: Master Thesis
Language:English
Published: 2019
Subjects:
Permian
Reservoir Characterization
Knurr
Fruholmen
Petrophysical Analysis
Hammerfest Basin
Tempelfjorden
Reservoir
Kolmule
Compaction
Rock Physics
Net-to-Gross
Gohta
Triassic
Shale Volume
Net Pay
Stø
Water Saturation
Ørn
Røye
Fluid Effect
Erosion
Tromsø Basin
Loppa High
Discovery
Carboniferous
Reservoir Properties
Permeability
Cretaceous
Uplift
Skalle
Jurassic
Barents Sea
Norway
Salina
Kobbe
Petrophysics
Petroleum Geology
Cement Volume
Porosity
Net Reservoir
NCS
Tromsø
Loppa
Hammerfest
Tempelfjord*
Online Access:http://hdl.handle.net/10852/70005
http://urn.nb.no/URN:NBN:no-73134
id ftoslouniv:oai:www.duo.uio.no:10852/70005
record_format openpolar
institution Open Polar
collection Universitet i Oslo: Digitale utgivelser ved UiO (DUO)
op_collection_id ftoslouniv
language English
topic Permian
Reservoir Characterization
Knurr
Fruholmen
Petrophysical Analysis
Hammerfest Basin
Tempelfjorden
Reservoir
Kolmule
Compaction
Rock Physics
Net-to-Gross
Gohta
Triassic
Shale Volume
Net Pay
Stø
Water Saturation
Ørn
Røye
Fluid Effect
Erosion
Tromsø Basin
Loppa High
Discovery
Carboniferous
Reservoir Properties
Permeability
Cretaceous
Uplift
Skalle
Jurassic
Barents Sea
Norway
Salina
Kobbe
Petrophysics
Petroleum Geology
Cement Volume
Porosity
Net Reservoir
NCS
spellingShingle Permian
Reservoir Characterization
Knurr
Fruholmen
Petrophysical Analysis
Hammerfest Basin
Tempelfjorden
Reservoir
Kolmule
Compaction
Rock Physics
Net-to-Gross
Gohta
Triassic
Shale Volume
Net Pay
Stø
Water Saturation
Ørn
Røye
Fluid Effect
Erosion
Tromsø Basin
Loppa High
Discovery
Carboniferous
Reservoir Properties
Permeability
Cretaceous
Uplift
Skalle
Jurassic
Barents Sea
Norway
Salina
Kobbe
Petrophysics
Petroleum Geology
Cement Volume
Porosity
Net Reservoir
NCS
Viga, Odd Fossaa
Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries
topic_facet Permian
Reservoir Characterization
Knurr
Fruholmen
Petrophysical Analysis
Hammerfest Basin
Tempelfjorden
Reservoir
Kolmule
Compaction
Rock Physics
Net-to-Gross
Gohta
Triassic
Shale Volume
Net Pay
Stø
Water Saturation
Ørn
Røye
Fluid Effect
Erosion
Tromsø Basin
Loppa High
Discovery
Carboniferous
Reservoir Properties
Permeability
Cretaceous
Uplift
Skalle
Jurassic
Barents Sea
Norway
Salina
Kobbe
Petrophysics
Petroleum Geology
Cement Volume
Porosity
Net Reservoir
NCS
description Exploration in the Barents Sea has shown to be difficult, due to the regional tectonic history to the area. Multiple uplift events, faulting and erosion make the well log data behave differently than expected in other areas on the NCS. This study focuses on the reservoirs in PermianTriassic- Jurassic and Cretaceous succession at the Loppa High area SW Barents Sea, with a, primary focus on Gohta, Salina and Skalle Discoveries. Mainly well log data from six wells has been used in the reservoir characterization: 7120/1-1, 7120/1-2, 7120/1-3 (Gohta), 7120/1- 4 S (Gohta Appraisal), 7120/2-3 S (Skalle) and 7220/10-1 (Salina). The Stø and Kolmule Formation represent the two main target reservoirs for both the Skalle and Salina Discovery, where both of these discoveries mainly consist of gas. The Gohta Discovery stands out from the two others by being located in Røye Formation, consisting of larger amount of carbonates. These formations (Kolmule, Stø, and Røye) are the main focus in the reservoir characterization, where petrophysical analysis and rock physics diagnostics are the two methods used. Petrophysical analysis techniques have been used to calculate the reservoir properties (e.g. shale volume, net-to-gross, porosity, permeability, and water saturation) in the reservoir zone, to provide an insight of the reservoir quality in the study area. The Cretaceous Kolmule Formation shows poorer reservoir quality compared with the Middle Jurassic Stø Formation, which is clearly shown in the amount of shale volume (17-23 % in Kolmule Formation and 7-13 % in Stø Formation) and the net-to-gross values (0.31-0.43 in Kolmule Formation and 0.97-0.99 in Stø Formation). The main contributor to the shale volume in the Stø Formation in the upper part, which is much shalier than the clean lower part of the formation. Both of these formations show high effective porosity values (17-23 % in Kolmule Formation and 14-22 % in Stø Formation). The Permian Røye Formation in well 7120/1-3 (Gohta Discovery) is the only formation containing a higher amount of oil. This formation differs from the two others by being located at a greater burial depth and the content of carbonate rocks. It is a result of relatively shallow burial depth of the central part of the southern Loppa High during Permian time resulting in carbonate buildups. However, the Røye Formation shows good reservoir quality in the discovery well, with relatively high effective porosity (11.5 %) and high net-to-gross value (0.551). Vp-depth trends have been utilized to estimate the uplift in the six wells in this study, based on the transition zone between the mechanical and chemical compaction. The uplift has been estimated to be between 950 m and 1150 m, which correlate well with the published data. In rock physics diagnostics different templates from literature, together with trends in the plots have been used to provide information about the lithology, cementation and fluid effects within the reservoir zones. The target reservoirs show particularly good results in the LMR plots, where the decreasing Vp in hydrocarbon zones is clear. In Røye Formation the main difference in these plots are the significantly higher values of Vp and Vs. Despite this, the formation due shows similar trends (decreasing Vp compared with Vs) in the fluid sensitivity plots (Vp/Vs versus AI, Vp versus Vs and LMR). Kolmule Formation in Skalle Discovery shows some poorer results in the rock physics diagnostics, which probably is due to high shale volume and that the hydrocarbon zone is located in the middle of the formation.
format Master Thesis
author Viga, Odd Fossaa
author_facet Viga, Odd Fossaa
author_sort Viga, Odd Fossaa
title Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries
title_short Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries
title_full Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries
title_fullStr Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries
title_full_unstemmed Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries
title_sort imaging reservoir properties of the permian- triassic- jurassic and cretaceous successions at loppa high, norwegian barents sea. examples from gohta, salina and skalle discoveries
publishDate 2019
url http://hdl.handle.net/10852/70005
http://urn.nb.no/URN:NBN:no-73134
long_lat ENVELOPE(15.124,15.124,69.019,69.019)
ENVELOPE(17.076,17.076,78.404,78.404)
ENVELOPE(7.683,7.683,62.800,62.800)
ENVELOPE(22.351,22.351,70.240,70.240)
geographic Barents Sea
Norway
Tromsø
Stø
Tempelfjorden
Skalle
Loppa
geographic_facet Barents Sea
Norway
Tromsø
Stø
Tempelfjorden
Skalle
Loppa
genre Barents Sea
Hammerfest
Hammerfest Basin
Loppa
Røye
Tempelfjord*
Tempelfjorden
Tromsø
genre_facet Barents Sea
Hammerfest
Hammerfest Basin
Loppa
Røye
Tempelfjord*
Tempelfjorden
Tromsø
op_relation http://urn.nb.no/URN:NBN:no-73134
Viga, Odd Fossaa. Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries. Master thesis, University of Oslo, 2019
http://hdl.handle.net/10852/70005
URN:NBN:no-73134
Fulltext https://www.duo.uio.no/bitstream/handle/10852/70005/5/MSc_Thesis_Odd_F_Viga_PEGG.pdf
_version_ 1766370213985517568
spelling ftoslouniv:oai:www.duo.uio.no:10852/70005 2023-05-15T15:38:50+02:00 Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries Viga, Odd Fossaa 2019 http://hdl.handle.net/10852/70005 http://urn.nb.no/URN:NBN:no-73134 eng eng http://urn.nb.no/URN:NBN:no-73134 Viga, Odd Fossaa. Imaging Reservoir Properties of the Permian- Triassic- Jurassic and Cretaceous successions at Loppa High, Norwegian Barents Sea. Examples from Gohta, Salina and Skalle Discoveries. Master thesis, University of Oslo, 2019 http://hdl.handle.net/10852/70005 URN:NBN:no-73134 Fulltext https://www.duo.uio.no/bitstream/handle/10852/70005/5/MSc_Thesis_Odd_F_Viga_PEGG.pdf Permian Reservoir Characterization Knurr Fruholmen Petrophysical Analysis Hammerfest Basin Tempelfjorden Reservoir Kolmule Compaction Rock Physics Net-to-Gross Gohta Triassic Shale Volume Net Pay Stø Water Saturation Ørn Røye Fluid Effect Erosion Tromsø Basin Loppa High Discovery Carboniferous Reservoir Properties Permeability Cretaceous Uplift Skalle Jurassic Barents Sea Norway Salina Kobbe Petrophysics Petroleum Geology Cement Volume Porosity Net Reservoir NCS Master thesis Masteroppgave 2019 ftoslouniv 2020-06-21T08:53:42Z Exploration in the Barents Sea has shown to be difficult, due to the regional tectonic history to the area. Multiple uplift events, faulting and erosion make the well log data behave differently than expected in other areas on the NCS. This study focuses on the reservoirs in PermianTriassic- Jurassic and Cretaceous succession at the Loppa High area SW Barents Sea, with a, primary focus on Gohta, Salina and Skalle Discoveries. Mainly well log data from six wells has been used in the reservoir characterization: 7120/1-1, 7120/1-2, 7120/1-3 (Gohta), 7120/1- 4 S (Gohta Appraisal), 7120/2-3 S (Skalle) and 7220/10-1 (Salina). The Stø and Kolmule Formation represent the two main target reservoirs for both the Skalle and Salina Discovery, where both of these discoveries mainly consist of gas. The Gohta Discovery stands out from the two others by being located in Røye Formation, consisting of larger amount of carbonates. These formations (Kolmule, Stø, and Røye) are the main focus in the reservoir characterization, where petrophysical analysis and rock physics diagnostics are the two methods used. Petrophysical analysis techniques have been used to calculate the reservoir properties (e.g. shale volume, net-to-gross, porosity, permeability, and water saturation) in the reservoir zone, to provide an insight of the reservoir quality in the study area. The Cretaceous Kolmule Formation shows poorer reservoir quality compared with the Middle Jurassic Stø Formation, which is clearly shown in the amount of shale volume (17-23 % in Kolmule Formation and 7-13 % in Stø Formation) and the net-to-gross values (0.31-0.43 in Kolmule Formation and 0.97-0.99 in Stø Formation). The main contributor to the shale volume in the Stø Formation in the upper part, which is much shalier than the clean lower part of the formation. Both of these formations show high effective porosity values (17-23 % in Kolmule Formation and 14-22 % in Stø Formation). The Permian Røye Formation in well 7120/1-3 (Gohta Discovery) is the only formation containing a higher amount of oil. This formation differs from the two others by being located at a greater burial depth and the content of carbonate rocks. It is a result of relatively shallow burial depth of the central part of the southern Loppa High during Permian time resulting in carbonate buildups. However, the Røye Formation shows good reservoir quality in the discovery well, with relatively high effective porosity (11.5 %) and high net-to-gross value (0.551). Vp-depth trends have been utilized to estimate the uplift in the six wells in this study, based on the transition zone between the mechanical and chemical compaction. The uplift has been estimated to be between 950 m and 1150 m, which correlate well with the published data. In rock physics diagnostics different templates from literature, together with trends in the plots have been used to provide information about the lithology, cementation and fluid effects within the reservoir zones. The target reservoirs show particularly good results in the LMR plots, where the decreasing Vp in hydrocarbon zones is clear. In Røye Formation the main difference in these plots are the significantly higher values of Vp and Vs. Despite this, the formation due shows similar trends (decreasing Vp compared with Vs) in the fluid sensitivity plots (Vp/Vs versus AI, Vp versus Vs and LMR). Kolmule Formation in Skalle Discovery shows some poorer results in the rock physics diagnostics, which probably is due to high shale volume and that the hydrocarbon zone is located in the middle of the formation. Master Thesis Barents Sea Hammerfest Hammerfest Basin Loppa Røye Tempelfjord* Tempelfjorden Tromsø Universitet i Oslo: Digitale utgivelser ved UiO (DUO) Barents Sea Norway Tromsø Stø ENVELOPE(15.124,15.124,69.019,69.019) Tempelfjorden ENVELOPE(17.076,17.076,78.404,78.404) Skalle ENVELOPE(7.683,7.683,62.800,62.800) Loppa ENVELOPE(22.351,22.351,70.240,70.240)

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