Nonlinear stress dependence of permeability; a mechanism for episodic fluid flow in accretionary wedges

Recent studies of the hydrogeology of accretionary wedges demonstrate that permeability is a dynamic property that depends upon the scale of observation and the prevailing stress state during measurement. We present results of laboratory geotechnical tests on sediments cored from the Costa Rica conv...

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Bibliographic Details
Published in:Geology (Boulder) 1999-03, Vol.27 (3), p.239-242
Main Authors: Bolton, Alistair J, Clennell, M. Ben, Maltman, Alex J
Format: Article
Language:English
Subjects:
accretionary wedges
Caribbean Plate
Caribbean region
Central America
Chemistry
Cocos Plate
consolidation
cores
Costa Rica
cycles
dilatancy
East Pacific
experimental studies
fine-grained materials
fluid dynamics
fluid pressure
fracture zones
Geology
Geophysics
laboratory studies
Leg 170
Marine
marine sediments
mechanical properties
Middle America Trench
nonlinear materials
North Pacific
Northeast Pacific
Ocean Drilling Program
Oceanography
ODP Site 1039
ODP Site 1040
ODP Site 1043
overconsolidated materials
overpressure
Pacific Ocean
periodicity
permeability
plate convergence
plate tectonics
pressure
sediments
shear
soil mechanics
solid Earth (tectonophysics)
stress
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Summary:Recent studies of the hydrogeology of accretionary wedges demonstrate that permeability is a dynamic property that depends upon the scale of observation and the prevailing stress state during measurement. We present results of laboratory geotechnical tests on sediments cored from the Costa Rica convergent margin during Ocean Drilling Program Leg 170. By measuring the permeability of samples of differing lithology before, during, and after shearing we show that hydrological behavior is linked to the consolidation state of the sediment at the onset of shear, and to the formation or reactivation of deformation fabrics. One sample obtained from a fault zone displayed a high permeability-effective stress dependence after being deformed at a high overconsolidation ratio. Under these conditions, shear zones in fine-grained sediments can dilate and thereby act as efficient fluid-flow conduits. Such stress-dependent permeability typifies the cyclic pressure build-up and release mechanisms (valving) invoked for many tectonic settings. We infer that a fracture permeability, opened up at high fluid pressures, is several times to several orders of magnitude greater than the matrix permeability. Our results help quantify the degree to which hydromechanical coupling can enhance flow in the actively deforming parts of accretionary wedges.
ISSN:0091-7613
1943-2682
DOI:10.1130/0091-7613(1999)027<0239:NSDOPA>2.3.CO;2