Laboratory observations of permeability enhancement by fluid pressure oscillation of in situ fractured rock
Publication date
2011
Authors
Elkhoury, J.E.
Niemeijer, A.
Brodsky, E.E.
Marone, C.
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Document Type
Article
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(c) UU Universiteit Utrecht, 2011
Abstract
We report on laboratory experiments designed to investigate the influence of pore
pressure oscillations on the effective permeability of fractured rock. Berea sandstone
samples were fractured in situ under triaxial stresses of tens of megapascals, and
deionized water was forced through the incipient fracture under conditions of steady and
oscillating pore pressure. We find that short‐term pore pressure oscillations induce
long‐term transient increases in effective permeability of the fractured samples. The
magnitude of the effective permeability enhancements scales with the amplitude
of pore pressure oscillations, and changes persist well after the stress perturbation.
The maximum value of effective permeability enhancement is 5 × 10-16 m2 with a
background permeability of 1 × 10−15 m2; that is, the maximum enhanced permeability
is 1.5 × 10−15 m2. We evaluate poroelastic effects and show that hydraulic storage
release does not explain our observations. Effective permeability recovery following
dynamic oscillations occurs as the inverse square root of time. The recovery indicates that
a reversible mechanism, such as clogging/unclogging of fractures, as opposed to an
irreversible one, like microfracturing, is responsible for the transient effective permeability
increase. Our work suggests the feasibility of dynamically controlling the effective
permeability of fractured systems. The result has consequences for models of earthquake
triggering and permeability enhancement in fault zones due to dynamic shaking from
near and distant earthquakes.
Keywords
permeability enhancement, earthquake models, fault zones