Frictional heating and pore pressure rise due to a fault slip
Tien-Chang Lee,Paul T. Delaney +1 more
TLDR
In this paper, the authors deal with frictional heating, pore pressure rise, and migration of fluid, and speculates upon their consequences for triggering of earthquakes and emission of earthquake light.Abstract:
Summary. Accurate estimation of frictional stress is crucial to determining the bounds of pre- and post-earthquake states of stress. A long-term average value of 10 MPa, deduced from heat flow data in the San Andreas fault zone, is frequently cited, but it may or may not represent the resistive stress of an individual slip event. Based on 1-D modelling, this paper deals with frictional heating, pore pressure rise, and migration of fluid, and speculates upon their consequences for triggering of earthquakes and emission of earthquake light. Analytic solutions are obtained for temperature and pore pressure rises due to frictional heating. Results are obtained for three heating models: 1, instantaneous heating; 11, constant heating rate; and 111, heating rate proportional to inverse square root of time. For the same total heat generation and physical parameters, solutions indicate that, for times less than twice the slip duration or distances with two thermal diffusion distances, temperature and pressure distributions are sensitive to heating models; at greater times and distances, they are insensitive to models. Though temperature rise due to I-m slip under 10MPa frictional stress may reach 200K or more on the slip surface, the rise is not measurable in practice at a distance beyond about 10 m from the slip surface. Estimates of pore pressure rise (0.2-2MPa) depends crucially upon permeability and slip duration. Darcy flow may exceed lO-'m s-' at one thermal diffusion distance; and immediately after the slip ends, reverse flow towards slip surface develops. Because the pore pressure front can advance beyond the temperature front by 100-1000 times, measurement of pore pressure variation is an alternative to temperature measurement for estimating frictional stress. A rise of 500Pa is measurable at 330m within 30 days for a fault slip with frictional heat production of 10MJm-2. It is speculated that the propagating pressure front created by an initial slip, rather than the fluid flow itself, may weaken the frictional strength elsewhere and lead to additional minor slips and perhaps a larger earthquake. With large frictional stress and displacement, heating may alsoread more
Citations
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Journal ArticleDOI
Heating and weakening of faults during earthquake slip
TL;DR: In this article, the authors suggest that the most relevant weakening processes in large crustal events are thermal, and to involve thermal pressurization of pore fluid within and adjacent to the deforming fault core, which reduces the effective normal stress and hence also the shear strength for a given friction coefficient.
Journal ArticleDOI
Earthquake ruptures with thermal weakening and the operation of major faults at low overall stress levels
TL;DR: In this article, the authors model a set of faults that are susceptible to flash heating of microscopic asperity contacts (within a rate-and-state framework) and thermal pressurization of pore fluid, and show that natural earthquakes will occur as slip pulses if faults operate at the minimum stress required for propagation.
Journal ArticleDOI
A fault constitutive relation accounting for thermal pressurization of pore fluid
TL;DR: In this article, the authors show that the threshold propagation distance at which stress drop starts to dominate over frictionally induced stress drop is proportional to the square root of hydraulic diffusivity times the elapsed time.
Journal ArticleDOI
Thermal decomposition of carbonates in fault zones: Slip-weakening and temperature-limiting effects
Jean Sulem,Vincent Famin +1 more
TL;DR: In this paper, the authors introduced the coupled effects of calcite volume loss, heat consumption, and CO2 production in the theoretical analysis of shear heating and thermal pressurization of pore fluids.
Book ChapterDOI
The habitat of fault-generated pseudotachylyte : Presence vs. absence of friction-melt
Richard H. Sibson,Virginia Toy +1 more
TL;DR: Fault-hosted pseudotachylyte is rare and largely restricted to crystalline host rocks as mentioned in this paper, and their apparent scarcity raises the question as to whether pseudotsycholyte is rarely generated (perhaps because of dynamic lowering of shear resistance).
References
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Book
Conduction of Heat in Solids
H. S. Carslaw,John Conrad Jaeger +1 more
TL;DR: In this paper, a classic account describes the known exact solutions of problems of heat flow, with detailed discussion of all the most important boundary value problems, including boundary value maximization.
Journal ArticleDOI
Theoretical basis of some empirical relations in seismology
Hiroo Kanamori,Don L. Anderson +1 more
TL;DR: In this article, an empirical relation involving seismic moment M, energy E, magnitude M, and fault dimension L (or area S) is discussed on the basis of an extensive set of earthquake data (M_S ≧ 6) and simple crack and dynamic dislocation models.
Journal ArticleDOI
Heat flow and energetics of the San Andreas Fault Zone
TL;DR: In this article, the authors show that there is no evidence for local factional heating of the main fault trace at any latitude over a 1000 km length from Cape Mendocino to San Bernardino, and average heat flow is high (∼2 HFU, ∼80 mW m−2) throughout the 550 km segment of the Coast Ranges that encloses the San Andreas fault zone in central California.
Journal ArticleDOI
Frictional heating, fluid pressure, and the resistance to fault motion
TL;DR: In this article, the authors studied the effect of pore fluid expansion caused by frictional heating on the factional resistance and temperature during an earthquake and a controlling influence on the physics of the earthquake process.
Journal ArticleDOI
Heat flow, stress, and rate of slip along the San Andreas Fault, California
TL;DR: In this article, the authors used the absence of a heat flow anomaly greater than ∼0.3 µcal/cm2/sec associated with the San Andreas fault to estimate the upper limit for the steady state or initial shear stress.