Th gme 05: Modeling of fault reactivation and fault slip in producing gas fields

Th gme 05: Modeling of fault reactivation and fault slip in producing gas fields

Wassing, B.B.T.

2015

Current methods which are used for seismic hazard analyses of production induced seismicity in The Netherlands are generally based on either empirical relations which link compaction strain and seismic release or simple relations between available fault area and seismic moment release. Physics based understanding of the impact of streb evolution on faults due to production is needed to reduce uncertainties and support the basic abumptions in seismological models and hazard abebments. Geomechanical analysis shows fault offsets, reservoir geometry and differential compaction play an important role in production induced fault reactivation. These effects are currently not accounted for in the hazard analyses. Both simplified 2D and full field 3D geomechanical models can be used to model the onset of reactivation - and identify faults which are prone to be reactivated. To get more insight into the seismic response of the faults, i.e. the extent of the rupture area and slip displacements, more advanced friction laws need to be incorporated. © Copyright 2015 EAGE.

Geo
PG - Petroleum Geosciences
ELSS - Earth, Life and Social Sciences
Geological Survey Netherlands
Geosciences
2015 Energy
Compaction
Friction
Gas industry
Geomechanics
Hazards
Induced Seismicity
Natural gas fields
Seismology
Differential compaction
Empirical relations
Fault reactivation
Geomechanical model

http://resolver.tudelft.nl/uuid:521f4001-36f1-4b01-b516-67c9f2d01ac8

533274

European Association of Geoscientists and Engineers, EAGE

9781510814202

2nd EAGE Workshop on Geomechanics and Energy: The Ground as Energy Source and Storage, 6-10

conference paper