Abstract
AbstractIn retrograde faults exhuming mafic rocks, shearing occurs in metamorphic and/or hydrothermally altered mineral assemblages whose frictional properties are not well known. Here, we present the results of laboratory shearing experiments on chlorite schist, epidotite, and hornblende‐dominated amphibolite and mixtures of these rocks and evaluate their frictional properties and microstructures. The experiments were conducted on powdered rock samples with starting grain size of <125 μm, at room temperature, under fluid‐saturated conditions and applied normal stress of 10 MPa. The results show that chlorite schist is relatively weak (friction coefficient of 0.36), whereas epidotite and amphibolite are strong (friction coefficients of 0.63 and 0.67, respectively). The friction of chlorite schist‐epidotite and chlorite schist‐amphibolite mixtures decreases nearly linearly with increasing chlorite content. Chlorite schist exhibits velocity‐strengthening behavior, epidotite is velocity‐weakening, and the amphibolite shows mostly velocity‐weakening friction. Mixtures show intermediate strength and velocity dependence of friction. Well‐developed striations formed on slip surfaces in samples with ≥50% chlorite schist. The epidotite slip surface exhibits a mixture of very fine particles and coarser crystals. Amphibolite slip surfaces have less very fine grains and are composed of subhedral to euheral needles. Few intragranular fractures are preserved, and we infer wear at contact asperities to be the likely cause of velocity‐weakening in our epidote gouges. Addition of chlorite to epidotite and amphibolite produces a striated slip surface and disrupts contacts between harder grains. Therefore, retrograde chlorite growth is expected to facilitate frictional weakening and stable slip in higher‐grade mineral assemblages exhumed to low‐temperature conditions.
Highlights
The largest earthquakes generally nucleate near the base of the seismogenic zone, under greenschist facies conditions (e.g., Jiang & Lapusta, 2017; Sibson, 1982)
The chlorite schist value from this study is similar to the value of 0.32 measured by Ikari et al (2009) for the same sample under similar conditions
We suggest that the experimental boundary conditions of our deformation apparatus favored rapid development of a localized slip surface in the chlorite schist end‐member (Figures 10c and 10d), preserving none or a minor component of the Riedel shear‐forming phase observed in the other studies
Summary
The largest earthquakes generally nucleate near the base of the seismogenic zone, under greenschist facies conditions (e.g., Jiang & Lapusta, 2017; Sibson, 1982). Greenschist to amphibolite facies mineral assemblages, formed near the base of the seismogenic zone, may host active shearing at shallower depths by exhumation through uplift and/or erosion (e.g., Abers et al, 1997; Norris & Cooper, 2007; Taylor et al, 2000). Consider a fault zone where the fault zone rocks include ferromagnesian minerals that experience exhumation and cooling from the base of the seismogenic zone to shallower conditions during progressive deformation. When cooling from amphibolite or greenschist to lower metamorphic facies, the amphibole species hornblende breaks down to chlorite and epidote, and to the amphibole species actinolite, if free water is present (e.g., Apted & Liou, 1983; Fagereng & Diener, 2011; Miyashiro, 1968). Faults exhuming greenschist to amphibolite facies mafic rocks can experience changes in frictional properties as mineral proportions change with increasing retrograde chlorite (+/− epidote) growth. If the bulk rock composition is suitable for FAGERENG AND IKARI
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