The University of Southampton
University of Southampton Institutional Repository

High-resolution architecture of a polygonal fault interval inferred from geomodel applied to 3D seismic data from the Gjallar Ridge, Vøring Basin, Offshore Norway

High-resolution architecture of a polygonal fault interval inferred from geomodel applied to 3D seismic data from the Gjallar Ridge, Vøring Basin, Offshore Norway
High-resolution architecture of a polygonal fault interval inferred from geomodel applied to 3D seismic data from the Gjallar Ridge, Vøring Basin, Offshore Norway
3D seismic data located in the Gjallar Ridge (Vøring Basin, offshore Norway) reveals a closely-spaced polygonal fault system affecting more than 800 m of homogeneous mud-dominated Quaternary and Tertiary sequences. As some faults reach the modern seafloor, they represent an active polygonal fault system at present day. Even if the processes remain unclear and are still under debate, it is generally agreed that the initiation of polygonal faults is the result of shallow burial dewatering of fine-grained unconsolidated sediments by volumetric compaction. 3D seismic data are commonly interpreted by propagating horizons automatically and by picking faults manually. However, in the case of polygonal fault intervals, this approach is time consuming due to the huge number of faults and because automatic propagation can be misleading. In this study, we applied a new technique of 3D seismic interpretation based on a sequential stratigraphy analysis, using the new PaleoScan© software (Eliis Company). It allowed us to build a 3D geological model computing more than 300 horizons within the faulted intervals. We then used the coherency attribute, depicting anomalies in the shape of seismic waveform like faults, in order to constrain a possible link between fault distribution and stratigraphic levels. Our approach allows fault throws to be calculated in milliseconds on any polygonal fault plane. The result shows that fault segments have been reactivated by dip-linkage. Distribution of faults depends on mechanical units, intervals characterized by different petrophysical properties, which are independent from lithological and diagenetic changes. According to these results, we propose a model showing the evolution of polygonal fault intervals in which faulting stages are separated by a quiescence phase during burial. A first tier of polygonal faults is initiated at a specific depth, according to the Cam–clay model. Then, following a period of quiescence during which mud-rich sediments continued to accumulate, new fault segments are initiated above the first mechanical unit and within this undeformed interval. New nucleated faults then connect downward to pre-existing underlying polygonal fault system, thus progressively increasing the thickness of the faulted interval.
polygonal faulting, 3D seismic geomodel, dip linkage, mechanical unit, fluid flow, PaleoScan© Software
0025-3227
134-151
Laurent, Dimitri
73d1dc10-6fe8-4552-98c8-c074494c855d
Gay, Aurélien
326b1ea4-ba4e-4806-bdc6-9425ce620ab7
Baudon, Catherine
d031b335-c35a-41b2-9d4d-ab0caec8558e
Berndt, Christian
d6db3f62-9891-4e8a-9210-b3aa6a8a4c22
Soliva, Roger
b6293498-ce17-411a-baa1-1d0eef4cac4b
Planke, Sverre
fe952765-8cb5-4337-abf1-6f3cb88fe7ee
Mourgues, Régis
098cda73-d142-4705-b17c-1154bde879e5
Lacaze, Sébastien
37d364ea-f783-4eb8-8a65-48a447c8d3fd
Pauget, Fabien
9795477e-e245-4dd1-ba04-e0b77c00d25e
Mangue, Marion
a1c8eef4-04b9-4b47-af8f-da158590563a
Lopez, Michel
dc4b53eb-1f7d-49c6-9e6d-e71d1cf694c7
Laurent, Dimitri
73d1dc10-6fe8-4552-98c8-c074494c855d
Gay, Aurélien
326b1ea4-ba4e-4806-bdc6-9425ce620ab7
Baudon, Catherine
d031b335-c35a-41b2-9d4d-ab0caec8558e
Berndt, Christian
d6db3f62-9891-4e8a-9210-b3aa6a8a4c22
Soliva, Roger
b6293498-ce17-411a-baa1-1d0eef4cac4b
Planke, Sverre
fe952765-8cb5-4337-abf1-6f3cb88fe7ee
Mourgues, Régis
098cda73-d142-4705-b17c-1154bde879e5
Lacaze, Sébastien
37d364ea-f783-4eb8-8a65-48a447c8d3fd
Pauget, Fabien
9795477e-e245-4dd1-ba04-e0b77c00d25e
Mangue, Marion
a1c8eef4-04b9-4b47-af8f-da158590563a
Lopez, Michel
dc4b53eb-1f7d-49c6-9e6d-e71d1cf694c7

Laurent, Dimitri, Gay, Aurélien, Baudon, Catherine, Berndt, Christian, Soliva, Roger, Planke, Sverre, Mourgues, Régis, Lacaze, Sébastien, Pauget, Fabien, Mangue, Marion and Lopez, Michel (2012) High-resolution architecture of a polygonal fault interval inferred from geomodel applied to 3D seismic data from the Gjallar Ridge, Vøring Basin, Offshore Norway. Marine Geology, 332-334, 134-151. (doi:10.1016/j.margeo.2012.07.016).

Record type: Article

Abstract

3D seismic data located in the Gjallar Ridge (Vøring Basin, offshore Norway) reveals a closely-spaced polygonal fault system affecting more than 800 m of homogeneous mud-dominated Quaternary and Tertiary sequences. As some faults reach the modern seafloor, they represent an active polygonal fault system at present day. Even if the processes remain unclear and are still under debate, it is generally agreed that the initiation of polygonal faults is the result of shallow burial dewatering of fine-grained unconsolidated sediments by volumetric compaction. 3D seismic data are commonly interpreted by propagating horizons automatically and by picking faults manually. However, in the case of polygonal fault intervals, this approach is time consuming due to the huge number of faults and because automatic propagation can be misleading. In this study, we applied a new technique of 3D seismic interpretation based on a sequential stratigraphy analysis, using the new PaleoScan© software (Eliis Company). It allowed us to build a 3D geological model computing more than 300 horizons within the faulted intervals. We then used the coherency attribute, depicting anomalies in the shape of seismic waveform like faults, in order to constrain a possible link between fault distribution and stratigraphic levels. Our approach allows fault throws to be calculated in milliseconds on any polygonal fault plane. The result shows that fault segments have been reactivated by dip-linkage. Distribution of faults depends on mechanical units, intervals characterized by different petrophysical properties, which are independent from lithological and diagenetic changes. According to these results, we propose a model showing the evolution of polygonal fault intervals in which faulting stages are separated by a quiescence phase during burial. A first tier of polygonal faults is initiated at a specific depth, according to the Cam–clay model. Then, following a period of quiescence during which mud-rich sediments continued to accumulate, new fault segments are initiated above the first mechanical unit and within this undeformed interval. New nucleated faults then connect downward to pre-existing underlying polygonal fault system, thus progressively increasing the thickness of the faulted interval.

This record has no associated files available for download.

More information

Published date: 1 December 2012
Keywords: polygonal faulting, 3D seismic geomodel, dip linkage, mechanical unit, fluid flow, PaleoScan© Software
Organisations: Marine Geoscience

Identifiers

Local EPrints ID: 346589
URI: http://eprints.soton.ac.uk/id/eprint/346589
ISSN: 0025-3227
PURE UUID: b3289b26-7d60-4e91-9e15-188924e2ebc3

Catalogue record

Date deposited: 02 Jan 2013 17:22
Last modified: 14 Mar 2024 12:39

Export record

Altmetrics

Contributors

Author: Dimitri Laurent
Author: Aurélien Gay
Author: Catherine Baudon
Author: Christian Berndt
Author: Roger Soliva
Author: Sverre Planke
Author: Régis Mourgues
Author: Sébastien Lacaze
Author: Fabien Pauget
Author: Marion Mangue
Author: Michel Lopez

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×