Abstract
It has been proposed that large strike-slip faults such as the San Andreas contain water in seal-bounded compartments. Arguments based on heat flow and stress orientation suggest that in most of the compartments, the water pressure is so high that the average shear strength of the fault is less than 20 MPa. We propose a variation of this basic model in which most of the shear stress on the fault is supported by a small number of compartments where the pore pressure is relatively low. As a result, the fault gouge in these compartments is compacted and lithified and has a high undisturbed strength. When one of these locked regions fails, the system made up of the neighboring high and low pressure compartments can become unstable. Material in the high fluid pressure compartments is initially underconsolidated since the low effective confining pressure has retarded compaction. As these compartments are deformed, fluid pressure remains nearly unchanged so that they offer little resistance to shear. The low pore pressure compartments, however, are overconsolidated and dilate as they are sheared. Decompression of the pore fluid in these compartments lowers fluid pressure, increasing effective normal stress and shear strength. While this effect tends to stabilize the fault, it can be shown that this dilatancy hardening can be more than offset by displacement weakening of the fault (ie, the drop from peak to residual strength). If the surrounding rock mass is sufficiently compliant to produce an instability, slip will propagate along the fault until the shear fracture runs into a low-stress region. Frictional heating and the accompanying increase in fluid pressure that are suggested to occur during shearing of the fault zone will act as additional destabilizers. However, significant heating occurs only after a finite amount of slip and therefore is more likely to contribute to the energetics of rupture propagation than to the initiation of the instability.
We present results of a one-dimensional dynamic Burridge-Knopoff-type model to demonstrate various aspects of the fluid-assisted fault instability described above. In the numerical model, the fault is represented by a series of blocks and springs, with fault rheology expressed by static and dynamic friction. In addition, the fault surface of each block has associated with it pore pressure, porosity and permeability. All of these variables are allowed to evolve with time, resulting in a wide range of phenomena related to fluid diffusion, dilatancy, compaction and heating. These phenomena include creep events, diffusion-controlled precursors, triggered earthquakes, foreshocks, aftershocks, and multiple earthquakes. While the simulations have limitations inherent to 1-D fault models, they demonstrate that the fluid compartment model can, in principle, provide the rich assortment of phenomena that have been associated with earthquakes.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Andrews, D J. (1989), Mechanics of Fault Junctions, J. Geophys. Res. 94, 9389–9397.
Ben-Zion, Y., and Rice, J. R. (1993), Earthquake Failure Sequences along a Celluar Fault Zone in a Three-dimensional Elastic Solid Containing Asperity and Nonasperity Regions, J. Geophys. Res. 98, 14, 109–14,131.
Ben-Zion, Y., and Rice, J. R. (1995), Slip Patterns and Earthquake Populations along Different Classes of Faults in Elastic Solids, J. Geophys. Res. 100, 12959–12983.
Blanpied, M. L., Lockner, D. A., and Byerlee, J. D. (1992). An Earthquake Mechanism Based on Rapid Sealing of Faults, Nature 358, 574–576.
Blanpied, M. L., Lockner, D. A., and Byerlee, J. D. (1995), Frictional Slip of Granite at Hydrothermal Conditions, J. Geophys. Res. 100, 13045–13064.
Burridge, R., and Knopoff, L. (1967), Model and Theoretical Seismicity, Bull. Seismol. Soc. Am. 57, 341–371.
Byerlee, J. D. (1978), Friction of Rocks, Pure and Appl. Geophys. 116, 615–626.
Byerlee, J. D. (1990), Friction, Overpressure and Fault Normal Compression, Geophys. Res. Lett. 17, 2109–2112.
Byerlee, J. D. (1992), The Change in Orientation of Subsidiary Shears near Faults Containing Pore Fluid under High Pressure, Tectonophysics 211, 295–303.
Byerlee, J. D. (1993), Model for Episodic Flow of High Pressure Water in Fault Zones before Earthquakes, Geology 21, 303–306.
Byerlee, J. D., and Savage, J. C. (1992), Coulomb Plasticity within the Fault Zone, Geophys. Res. Lett. 19, 2341–2344.
Carlson, J. M., and Langer, J. S. (1989), Mechanical Model of an Earthquake, Phys. Rev. A 40, 6470–6484.
Carlson, J. M., Langer, J. S., Shaw, B., and Tang, C. (1991), Intrinsic Properties of a Burridge- Knopoff Model of a Fault, Phys. Rev. A 44, 884–897.
Dieterich, J. H. (1972), Time-dependent Friction as a Possible Mechanism for Aftershocks, J. Geophys. Res. 77, 3771–3781.
Dieterich, J. H. (1978), Time-dependent Friction and the Mechanics of Stick Slip, Pure and Appl. Geophys. 116, 790–806.
Fredrich, J. T., and Evans, B., Strength recovery along simulated faults by solution transfer processes. In 33rd U.S. Rock Mechanics Symposium (eds. Tillerson, J. R., and Warersik, W. R.) ( Balkema, Rotterdam 1992 ) pp. 121 – 130.
Hickman, S. H. (1991), Stress in the Lithosphere and the Strength of Active Faults, Rev. Geophys., IUGG Report, 759 – 775.
Johnston, M. J. S., Linde, A. T., Gladwin, M. T., and Borcherdt, R. D. (1987), Fault Failure with Moderate Earthquakes, Tectonophysics 144, 189–206.
Lachenbruch, A. H. (1980), Frictional Heating, Fluid Pressure, and the Resistance to Fault Motion, J. Geophys. Res. 85, 6097–6112.
Lachenbruch, A. H., and Sass, J. H. (1980), Heat Flow and Energetics of the San Andreas Fault Zone, J. Geophys. Res. 85, 6185–6222.
Li, Y.-G., Vidale, J. E., Aki, K., Marone, C. J., and Lee, W. H. K. (1994), Fine Structure of the Landers Fault Zone: Segmentation and the Rupture Process, Science 265, 367–370.
Lockner, D. A., Rock failure. In AGU Handbook of Physical Constants (ed. Ahrens, T. J.) (Am. Geophys. Union, Washington, D.C. 1995) 3–10, 127–147.
Lockner, D. A., and Byerlee, J. D. (1993), How Geometric Constraints Contribute to the Weakness of Mature Faults, Nature 363, 250–252.
Lockner, D. A., and Byerlee, J. D. (1994), Dilatancy in Hydraulically Isolated Faults and the Suppression of Instability, Geophys. Res. Lett. 21, 2353–2356.
Lockner, D. A., Okubo, P. G., and Dieterich, J. H. (1982), Containment of Stick-slip Failures on a Simulated Fault by Pore Fluid Injection, Geophys. Res. Lett. 9, 801–804.
Marone, C., and Kilgore, B. (1993), Scaling of the Critical Slip Distance for Seismic Faulting with Shear Strain in Fault Zones, Nature 362, 618–621.
Marone, C., Raleigh, C. B., and Scholz, C. H. (1990), Frictional Behavior and Constitutive Modelling of Simulated Fault Gouge, J. Geophys. Res. 95, 7007–7025.
Moore, D. E., Lockner, D. A., and Byerlee, J. D. (1994), Reduction of Permeability in Granite at Elevated Temperatures, Science 265, 1558–1561.
Moore, D. E., Summer, R., and Byerlee, J. D. (1986), The Effects of Sliding Velocity on the Frictional and Physical Properties of Heated Fault Gouge, Pure and Appl. Geophys. 124, 31–52.
Morrow, C., Radney, B., and Byerlee, J., Frictional strength and the effective pressure law of montmorillonite and illite clays. In Fault Mechanics and Transport Properties of Rocks(eds. Evans, B., and Wong, T.-f.) ( Academic Press, London 1992 ) pp. 69 – 88.
Morrow, C. A., and Byerlee, J. D. (1989), Experimental Studies of Compaction and Dilatancy during Frictional Sliding on Faults Containing Gouge, J. Struct. Geol. 11, 815–825.
Nur, A., and Booker, J. R. (1972), Aftershocks Caused by Pore Fluid Flow? Science 175, 885–887.
Reinen, L. A., Weeks, J. D., and Tullis, T. E. (1994), The Frictional Behavior of Lizardite and Antigorite Serpentinites: Experiments, Constitutive Models, and Implications for Natural Faults, Pure and Appl. Geophys. 143, 317–358.
Rice, J. R., Fault stress states, pore pressure distributions, and the weakness of the San Andreas fault. In Fault. Mechanics and Transport Properties of Rocks(eds. Evans, B., and Wong, T.-f.) ( Academic Press, London 1992 ) pp. 475 – 503.
Rice, J. R. (1993), Spatio-temporal Complexity of Slip on a Fault, J. Geophys. Res. 98, 9885–9907.
Robertson, E. C. (1983), Relationship of Fault Displacement to Gouge and Breccia Thickness, Trans. A.I.M.E. 35, 1426–1432.
Rudnicki, J. W., and Chen, C.-H. (1988), Stabilization of Rapid Frictional Slip on a Weakening Fault by Dilatant Hardening, J. Geophys. Res. 93, 4745–4757.
Scholz, C. H., Sykes, L. R. and Aggarwal, Y. P. (1973), Earthquake Prediction: A Physical Basis, Science 181, 803–810.
Sibson, R. H. (1982), Fault Zone Models, Heat Flow, and the Depth Distribution of Earthquakes in the Continental Crust of the United States, Bull. Seismol. Soc. Am. 72, 151–163.
Sleep, N. H., and Blanpied, M. L. (1992), Creep, Compaction and the Weak Rheology of Major Faults, Nature 359, 687–692.
Sleep, N. H., and Blanpied, M. L. (1994), Ductile Creep and Compaction: A Mechanism for Transiently Increasing Fluid Pressure in Mostly Sealed Fault Zones, Pure and Appl. Geophys. 143, 9–40.
Walther, J. V., Fluid dynamics during progressive regional metamorphism. In The Role of Fluids In Crustal Processes(ed. Council, N. R.) (National Academy Press, Washington, D.C. 1990 ) pp. 64 – 71.
Wesson, R. L. (1988), Dynamics of Fault Creep, J. Geophys. Res. 93, 8929–8951.
Zoback, M. D. et al. (1987), New Evidence on the State of Stress of the San Andreas Fault System, Science 238, 1105–1111.
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 1995 Birkhäuser Verlag
About this chapter
Cite this chapter
Lockner, D.A., Byerlee, J.D. (1995). An Earthquake Instability Model Based on Faults Containing High Fluid-pressure Compartments. In: Wang, R., Aki, K. (eds) Mechanics Problems in Geodynamics Part I. Pageoph Topical Volumes. Birkhäuser Basel. https://doi.org/10.1007/978-3-0348-9065-6_18
Download citation
DOI: https://doi.org/10.1007/978-3-0348-9065-6_18
Publisher Name: Birkhäuser Basel
Print ISBN: 978-3-7643-5104-5
Online ISBN: 978-3-0348-9065-6
eBook Packages: Springer Book Archive