Opposite Variations for Pore Pressure on and off the Fault During Simulated Earthquakes in the Laboratory

IF 3.9 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Journal of Geophysical Research: Solid Earth Pub Date : 2024-09-20 DOI:10.1029/2024JB028829
Dong Liu, Nicolas Brantut, Franciscus M. Aben
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Abstract

We measured the spatiotemporal evolution of pore pressure on- and off-fault during failure and slip in initially intact Westerly granite under triaxial conditions. The pore pressure perturbations in the fault zone and the surrounding bulk presented opposite signs upon shear failure, resulting in large pore pressure gradients over small distances (up to 10 MPa/cm). The on-fault pore pressure dropped due to localized fault dilation associated with fracture coalescence and fault slip, and the off-fault pore pressure increased due to bulk compaction resulting from the closure of dilatant microcracks mostly parallel to the maximum compression axis. We show that a reduction in bulk porosity and relatively undrained conditions during failure are necessary for the presence of the off-fault pore pressure elevation. Considering this phenomenon as a consequence of a main shock, we further show that off-fault pore pressure increase has the potential to trigger neighboring fault instabilities. In nature, we expect the phenomenon of off-fault pore pressure increase to be most relevant for misoriented faults, where the pre-rupture stresses can be large enough to reach the dilatancy threshold in the wall rocks.

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实验室模拟地震期间断层内外孔隙压力的相反变化
我们在三轴条件下测量了最初完整的韦斯特利花岗岩在破坏和滑移过程中断层内外孔隙压力的时空演变。在发生剪切破坏时,断层区的孔隙压力扰动与周围岩体的孔隙压力扰动呈现相反的迹象,导致小距离上的孔隙压力梯度较大(高达 10 兆帕/厘米)。断层上的孔隙压力因断裂凝聚和断层滑移引起的局部断层扩张而下降,而断层外的孔隙压力则因大部分平行于最大压缩轴的扩张微裂缝闭合导致的体层压实而上升。我们的研究表明,断层外孔隙压力升高的出现离不开破坏过程中体积孔隙度的降低和相对不排水的条件。考虑到这一现象是主冲击的结果,我们进一步证明断层外孔隙压力升高有可能引发邻近断层的不稳定。在自然界中,我们预计断层外孔隙压力增大现象与错向断层最为相关,在错向断层中,破裂前应力大到足以达到岩壁岩石的扩张阈值。
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来源期刊
Journal of Geophysical Research: Solid Earth
Journal of Geophysical Research: Solid Earth Earth and Planetary Sciences-Geophysics
CiteScore
7.50
自引率
15.40%
发文量
559
期刊介绍: The Journal of Geophysical Research: Solid Earth serves as the premier publication for the breadth of solid Earth geophysics including (in alphabetical order): electromagnetic methods; exploration geophysics; geodesy and gravity; geodynamics, rheology, and plate kinematics; geomagnetism and paleomagnetism; hydrogeophysics; Instruments, techniques, and models; solid Earth interactions with the cryosphere, atmosphere, oceans, and climate; marine geology and geophysics; natural and anthropogenic hazards; near surface geophysics; petrology, geochemistry, and mineralogy; planet Earth physics and chemistry; rock mechanics and deformation; seismology; tectonophysics; and volcanology. JGR: Solid Earth has long distinguished itself as the venue for publication of Research Articles backed solidly by data and as well as presenting theoretical and numerical developments with broad applications. Research Articles published in JGR: Solid Earth have had long-term impacts in their fields. JGR: Solid Earth provides a venue for special issues and special themes based on conferences, workshops, and community initiatives. JGR: Solid Earth also publishes Commentaries on research and emerging trends in the field; these are commissioned by the editors, and suggestion are welcome.
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