Generation of oxidising fluids by comminution of fault rocks

J. Kameda¹,

¹Department of Earth and Planetary Sciences, Faculty of Science, Hokkaido University, N10 W8, Sapporo, 060-0810, Japan

A. Okamoto²

²Graduate School of Environmental Studies, Tohoku University, Sendai, 980-8579, Japan

Affiliations | Corresponding Author | Cite as | Funding information

Geochemical Perspectives Letters v19 | doi: 10.7185/geochemlet.2131
Received 13 November 2020 | Accepted 20 September 2021 | Published 29 October 2021

Published by the European Association of Geochemistry
under Creative Commons License CC BY-NC-ND 4.0

Keywords: fault zone, mechanochemical, reactive oxygen species, H₂O₂, corrosion



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Abstract

Mechanochemical reactions exert a crucial control on the chemical environments of crustal fault zones during co-seismic and post-seismic periods. Comminution due to faulting causes activation of fault rock surfaces, such as the production of reactive radical species. In this study, we report on the generation of H₂O₂ by immersion of comminuted sedimentary, igneous, and metamorphic rocks that are broadly representative of those present at a variety of depths in subduction zones. Our experiments demonstrate that fresh surfaces of these rocks have an H₂O₂ productivity of 1.3–10.4 nmol m⁻² (mean = 5.4 nmol m⁻²). In a natural fault zone environment, H₂O₂ produced after a slip event is likely to react with Fe-bearing mineral surfaces or Fe²⁺ in porewater, or thermally decompose to produce more oxidative ·OH. The oxidising fluid produced by fault rupture in one patch may spread and induce corrosion and degradation of surrounding fault zones. These chemical processes are likely to be important factors influencing the interaction between neighbouring seismic activities.

Figures

Figure 1 H₂O₂ productivity of the analysed samples. Error bars for H₂O₂ productivity were estimated from the equation for the standard addition method (Larsen et al., 1973). The pH of the solution after the experiment (during the duplicate analyses) and the concentration of FeO in the rock samples are also shown.	Figure 2 H₂O₂ productivity vs. number of corners shared between silica tetrahedra (weighted mean) for the analysed rocks. The open symbol is data for the experiment using 0.01 M NaCl solution. Data and regression line from Hurowitz et al. (2007) are also shown.
Figure 1	Figure 2

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Introduction

Frictional slip on a fault zone causes comminution and wearing of fault rocks, producing highly reactive fine particles (Sammis et al., 1986

Sammis, C.G., Osborne, R.H., Anderson, J.L., Banerdt, M., White, P. (1986) Self-similar cataclasis in the formation of fault gouge. Pure and Applied Geophysics 124, 53–78.

; Scholz, 2002

Scholz, C.H. (2002) The mechanics of earthquake and faulting. Second Edition, Cambridge University Press, Cambridge.

). Radical species such as Si· and SiO· are commonly created on such particles of silicate minerals owing to homolytic rupture of Si–O covalent bonds (Hochstrasser and Antonini, 1972

Hochstrasser, G., Antonini, J.F. (1972) Surface states of pristine silica surfaces I. ESR studies of Es’ dangling bonds and of CO₂-adsorbed radicals. Surface Science 32, 644–664.

; Narayanasamy and Kubicki, 2005

Narayanasamy, J., Kubicki, J.D. (2005) Mechanism of Hydroxyl Radical Generation from a Silica Surface: Molecular Orbital Calculations. The Journal of Physical Chemistry B 109, 21796–21807.

). Hydrogen (H₂) is a typical product that is generated by reaction between Si· and water molecules within a fault zone. The production of H₂ by the interaction of fluids and comminuted rocks has been demonstrated by laboratory experiments (Kita et al., 1982

Kita, I., Matsuo, S., Wakita, H. (1982) H₂ generation by reaction between H₂O and crushed rock: An experimental study on H₂ degassing from the active fault zone. Journal of Geophysical Research: Solid Earth 87, 10789–10795.

; Kameda et al., 2003

Kameda, J., Saruwatari, K., Tanaka, H. (2003) H₂ generation in wet grinding of granite and single-crystal powders and implications for H₂ concentration on active faults. Geophysical Research Letters 30, 2063, doi: 10.1029/2003GL018252.

; Hirose et al., 2011

Hirose, T., Kawagucci, S., Suzuki, K. (2011) Mechanoradical H₂ generation during simulated faulting: Implications for an earthquake-driven subsurface biosphere. Geophysical Research Letters 38, L17303, doi: 10.1029/2011GL048850.

) and that associated with seismic activity has been observed by field survey (Wakita et al., 1980

Wakita, H., Nakamura, Y., Kita, I., Fujii, N., Notsu, K. (1980) Hydrogen release: New indicator of fault activity. Science 210, 188–190, doi: 10.1126/science.210.4466.188.

; Ito et al., 1999

Ito, T., Nagamine, K., Yamamoto, K., Adachi, M., Kawabe, I. (1999) Preseismic hydrogen gas anomalies caused by stress-corrosion process preceding earthquakes. Geophysical Research Letters 26, 2009–2012.

). In addition, numerous studies have demonstrated that pulverisation of pure powders of minerals forming igneous rocks can produce oxidising compounds such as hydrogen peroxide (H₂O₂), superoxide (O₂·⁻), and hydroxy (·OH) radicals (Schoonen et al., 2006

Schoonen, M.A.A., Cohn, C.A., Roemer, E., Laffers, R., Simon, S.R., O’Riordan, T. (2006) Mineral-induced formation of reactive oxygen species. Reviews in Mineralogy and Geochemistry 64, 179–221.

; Hurowitz et al., 2007

Hurowitz, J.A., Tosca, N.J., McLennan, S.M., Schoonen, M.A.A. (2007) Production of hydrogen peroxide in Martian and lunar soils. Earth and Planetary Science Letters 255, 41–52, doi: 10.1016/j.epsl.2006.12.004.

; Hendrix et al., 2019

Hendrix, D.A., Port, S.T., Hurowitz, J.A., Schoonen, M.A. (2019) Measurement of OH* generation by pulverized minerals using electron spin resonance spectroscopy and implications for the reactivity of planetary regolith. GeoHealth 3, 28–42, doi: 10.1029/2018GH000175.

), which are termed “reactive oxygen species” or “ROS”. ROS are formed by human activities such as mining, which produces fine particles of rocks and minerals (Schoonen et al., 2006

). ROS are also formed due to reaction with reactive secondary minerals and photochemistry in soils and sediments (e.g., Georgiou et al., 2015

Georgiou, C.D., Sun, H.J., McKay, C.P., Grintzalis, K., Papapostolou, I., Zisimopoulos, D., Panagiotidis, K., Zhang, G., Koutsopoulou, E., Christidis, G.E., Margiolaki, I. (2015) Evidence for photochemical production of reactive oxygen species in desert soils. Nature Communications 6, 7100, doi: 10.1038/ncomms8100.

). Because fault activity causes comminution of fault rocks, it can be assumed that ROS are also produced within fault zones. Moreover, such ROS may modify the chemical and even physical state of the fault zone. For example, some lithologies such as shales have been shown to undergo a variety of degradation on interaction with H₂O₂ (formation of cracks and voids, decomposition and dissolution of constituent materials, etc.), which results in modification of their hydromechanical properties at varying rates depending on temperature (Chen et al., 2017

Chen, Q., Kang, Y., You, L., Yang, P., Zhang, X., Cheng, Q. (2017) Change in composition and pore structure of Longmaxi black shale during oxidative dissolution. International Journal of Coal Geology 172, 95–111.

; Zhou et al., 2018

Zhou, Y., Lei, Y., Cheng, W., Yu, W. (2018) Enhance low temperature oxidization of shale gas recovery using hydrogen peroxide. Journal of Petroleum Science and Engineering 164, 523–530.

; Yu et al., 2019

Yu, W.G., Lei, J., Wang, T., Chen, W. (2019) H₂O₂-enhanced shale gas recovery under different thermal conditions. Energies 12, 2127, doi: 10.3390/en12112127.

). Thus, the production and diffusion of oxidising compounds by a seismic event can potentially degrade surrounding fault zones and stimulate subsequent fault activity.

In this study, we examine the production of H₂O₂ by reaction between water and ground rock samples at ambient conditions. The samples are sedimentary, metamorphic, and igneous rocks that may constitute plate boundaries at various depths in subduction zones (Hacker et al., 2003

Hacker, B.R., Peacock, S.M., Abers, G.A., Holloway, S.D. (2003) Subduction factory 2. Are intermediate-depth earthquakes in subducting slabs linked to metamorphic dehydration reactions? Journal of Geophysical Research: Solid Earth 108, 2030, doi: 10.1029/2001JB001127.

; Kimura et al., 2012

Kimura, G., Yamaguchi, A., Hojo, M., Kitamura, Y., Kameda, J., Ujiie, K., Hamada, Y., Hamahashi, M., Hina, S. (2012) Tectonic mélange as fault rock of subduction plate boundary. Tectonophysics 568, 25–38.

; Kameda et al., 2017

Kameda, J., Inoue, S., Tanikawa, W., Yamaguchi, A., Hamada, Y., Hashimoto, Y., Kimura, G. (2017) Alteration and dehydration of subducting oceanic crust within subduction zones: implications for decollement step-down and plate-boundary seismogenesis. Earth Planets and Space 69, 52, doi: 10.1186/s40623-017-0635-1.

). Our results show that oxidising fluid can be easily produced throughout the plate boundary zone after an earthquake. On the basis of our findings, we discuss the importance of the chemical aspects of fluids on fault behaviours.

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Samples and Experimental Methods

We analysed five natural rock samples: shale and oceanic basalt from the Cretaceous accretionary complex (Shimanto belt, Japan), and three basic schist samples from the high pressure Sanbagawa metamorphic belt, Japan. The basic schist samples (basic schist 1, basic schist 2, and basic schist 3) were taken from the chlorite, garnet, and albite–biotite zones of the Sanbagawa belt, respectively, which correspond to pressure-temperature (P-T) conditions ranging from greenschist to epidote-amphibolite facies (∼300 to ∼550 °C; Enami et al., 1994

Enami, M., Wallis, S.R., Banno, Y. (1994) Paragenesis of sodic pyroxene-bearing quartz schists: implications for P-T history of the Sanbagawa belt. Contributions to Mineralogy and Petrology 116, 182–198.

). For comparison, quartz sand (Wako Purer Chemicals) was also used for the experiments.

Whole rock major element concentrations of the rock samples were determined by an X-ray fluorescence spectrometer (XRF; Rigaku 25X Primus IV) using the conventional glass bead method. The Fe²⁺/ΣFe ratios were determined by wet chemical analyses. Mineral compositions were analysed by X-ray diffraction analysis (XRD; MAC Science MX-Labo), and the obtained XRD patterns were used for quantitative analysis by RockJock software (Eberl, 2003

Eberl, D.D. (2003) User’s guide to RockJock-A program for determining quantitative mineralogy from powder X-ray diffraction data. USGS Open-file Report 03–78.

).

The grinding experiments were carried out by using a planetary-type ball mill apparatus (P6; Fritsch). An amount of 3 g of each powder was loaded into a zirconia mill pot and was processed at 250–300 rpm for 5 min. The freshly ground powders with the post-grinding grain size of ∼0.5 μm (estimated from the surface area data described below, assuming uniform spherical particles) were then mixed with pure water (Direct-Q 3UV, Merck; pH = 5.84) in a Teflon beaker at room temperature (∼22 °C), and settled for 10–20 min. The H₂O₂ concentrations of the filtered solutions were then measured with the Scopoletin-Horseradish peroxidase (HRP) Fluorometric method using a fluorometer (RF-5300PC; Shimazu). The post-experiment pH of the solutions was also measured. The specific surface areas of the processed powders were measured by the Brunauer-Emmett-Teller (BET) method using an automated sorption analyser (Autosorb, Quantachrome Instruments). More details on the samples and experimental methods are described in the Supplementary Information.

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Results

Our experiments demonstrated that all of the studied samples were able to produce H₂O₂ by mechanical activation and subsequent immersion in water. Figure 1 shows the H₂O₂ productivity of each sample (nmol m⁻²), which is calculated from the H₂O₂ concentration of the reacting fluid (the background H₂O₂ concentration of 0.060 μmol L⁻¹ was subtracted from the measured concentration) normalised to the total surface area of the ground powders, as well as pH of the reacted solution and Fe²⁺ content in the solid samples (Tables S-1, S-2). The two analysed quartz samples have values of 0.55 and 0.44 nmol m⁻², which are slightly higher than previous results (0.2–0.3 nmol m⁻²; Hurowitz et al., 2007

). Factors such as different temperatures, pH of the matrix, reaction time, hydration state of the samples, etc. could explain the differences. The H₂O₂ productivities of the natural rock samples are generally one order of magnitude greater than those of quartz, ranging from 1.3 nmol m⁻² (shale) to 10.4 nmol m⁻² (basic schist 3) with a mean value of ∼5.4 nmol m⁻². No obvious correlation was found between the H₂O₂ productivities and pH or Fe²⁺ content.

**Figure 1** H₂O₂ productivity of the analysed samples. Error bars for H₂O₂ productivity were estimated from the equation for the standard addition method (Larsen *et al.*, 1973
Larsen, I.L., Hartmann, N.A., Wagner, J.J. (1973) Estimating precision for the method of standard additions. *Analytical Chemistry* 45, 1511–1513.
). The pH of the solution after the experiment (during the duplicate analyses) and the concentration of FeO in the rock samples are also shown.

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Discussion

Although the actual mechanism of H₂O₂ production from pulverised mineral surfaces is not completely understood, Hendrix et al. (2019)

argued that Si−O· on a newly created mineral surface reacts with H₂O to generate H₂O₂ as follows:

Hurowitz et al. (2007

) conducted pulverisation experiments using various pure mineral types and found that H₂O₂ productivity depends on the crystallographic nature of silicate minerals, with productivity increasing with a decreasing number of corners shared between Si (Al) tetrahedra (here termed the “c” number; Fig. 2). For example, tectosilicate minerals such as quartz and plagioclase have c = 4 and show the lowest H₂O₂ productivity of <1.0 nmol m⁻² of other types of silicate minerals with c < 4 (Hurowitz et al., 2007

; Fig. 2). As the present work used rock samples that included different types of silicate minerals, the weighted mean of c of each sample was estimated by XRD analysis (Table S-3). Figure 2 presents the relationship between H₂O₂ productivity and c of the analysed rock samples, and shows that the data are broadly consistent with the results of Hurowitz et al. (2007)

. Our results reveal that H₂O₂ can be generated by activation of natural rocks irrespective of their type (i.e. sedimentary, metamorphic, and igneous rocks), and the amount generated is likely to depend on the mineral composition of the rock.

**Figure 2** H₂O₂ productivity vs. number of corners shared between silica tetrahedra (weighted mean) for the analysed rocks. The open symbol is data for the experiment using 0.01 M NaCl solution. Data and regression line from Hurowitz *et al.* (2007)
Hurowitz, J.A., Tosca, N.J., McLennan, S.M., Schoonen, M.A.A. (2007) Production of hydrogen peroxide in Martian and lunar soils. *Earth and Planetary Science Letters* 255, 41–52, doi: 10.1016/j.epsl.2006.12.004.
are also shown.

Stability of H₂O₂ in fault zones following slip. Since fault movement causes comminution of fault rocks, H₂O₂ is expected to be produced by the reaction with porewater after an earthquake event. Furthermore, larger slip events may also lead to greater amount of comminution (Scholz, 2002

Scholz, C.H. (2002) The mechanics of earthquake and faulting. Second Edition, Cambridge University Press, Cambridge.

; Hirose et al., 2012

Hirose, T., Mizoguchi, K., Shimamoto, T. (2012) Wear processes in rocks at slow to high slip rates. Journal of Structural Geology 38, 102–116, doi: 10.1016/j.jsg.2011.12.007.

), which would produce more H₂O₂. In a natural fault zone environment, generated H₂O₂ reacts with Fe-bearing mineral surfaces or Fe²⁺ in porewater to produce more oxidative ·OH, as follows (i.e. the Fenton reaction):

In addition, H₂O₂ decomposes to two ·OH at high temperature conditions. The rate coefficient of the decomposition reaction is described as k = 6.4 × 10⁵ exp(−71 kJ mol⁻¹ / RT) s⁻¹ (Takagi and Ishigure, 1985

Takagi, J., Ishigure, K. (1985) Thermal decomposition of hydrogen peroxide and its effect on reactor water monitoring of boiling water reactors. Nuclear Science and Engineering 89, 177.

). This suggests that the half-life of H₂O₂ (i.e. ln(2)/k) is 158 min at 100 °C but is only ∼1 min at 200 °C. In the supercritical condition (T > 374 °C), the activation energy of the decomposition reaction can be higher (182 kJ mol⁻¹; Croiset et al., 2004

Croiset, E., Rice, S.F., Hanush, R.G. (2004) Hydrogen peroxide decomposition in supercritical water. Reactors, Kinetics, and Catalysis 43, 2343–2352.

), but the half-life is again very short (e.g., several seconds at 400 °C). Thus, it is presumed that H₂O₂ quickly decomposes to ·OH after an earthquake, and fluid containing these oxidative compounds may diffuse along the fault zone.

Influence of oxidising fluid generation on surrounding fault zones. In general, an earthquake does not occur in isolation but occurs as part of a sequence controlled by physical processes such as stress perturbation (Scholz, 2002

Scholz, C.H. (2002) The mechanics of earthquake and faulting. Second Edition, Cambridge University Press, Cambridge.

). Porewater diffusion is usually invoked as a reason for aftershock sequence (e.g., Nur and Booker, 1972

Nur, A., Booker, J.R. (1972) Aftershocks caused by pore fluid flow? Science 175, 885–887.

), but only the physical aspect of water (i.e. fluid pressure) has been argued in these models. Our study indicates the importance of chemical interaction between the fluid and surrounding fault zones. Specifically, generation of highly oxidising fluid can potentially promote corrosion of nearby fault zones and stimulate further fault activity. Such oxidising fluid is thought to interact with Fe-bearing minerals as well as organic compounds (Chen et al., 2017

; Zhou et al., 2018

Zhou, Y., Lei, Y., Cheng, W., Yu, W. (2018) Enhance low temperature oxidization of shale gas recovery using hydrogen peroxide. Journal of Petroleum Science and Engineering 164, 523–530.

). ·OH oxidises even graphite (Wang and Zhang, 2018

Wang, X., Zhang, L. (2018) Green and facile production of high-quality graphene from graphite by the combination of hydroxyl radical and electrical exfoliation. RSC Advances 8, 40621.

), a common product of the thermal maturation of organic compounds in metamorphic rocks, and may therefore degrade fault zones containing such minerals and materials. In natural examples, degradation or consumption of graphite has been observed in some fault zones (Nishiyama et al., 1990

Nishiyama, T. (1990) CO₂-metasomatism of a metabasite block in a serpentine mélange from the Nishisonogi metamorphic rocks, southwest Japan. Contributions to Mineralogy and Petrology 104, 35–46.

; Kretz, 1996

Kretz, R. (1996) Graphite deformation in marble and mylonitic marble, Grenville Province, Canadian Shield. Journal of Metamorphic Geology 14, 399–412.

; Nakamura et al., 2015

Nakamura, Y., Oohashi, K., Toyoshima, T., Satish-Kumar, M., Akai, J. (2015) Strain-induced amorphization of graphite in fault zones of the Hidaka metamorphic belt, Hokkaido, Japan. Journal of Structural Geology 72, 142–161.

), and the involvement of oxidising fluids in these processes has been suggested (Nishiyama, 1990

; Okamoto et al., 2021

Okamoto, A., Oyanagi, R., Yoshida, K., Uno, M., Shimizu, H., Satish-Kumar, M. (2021) Rupture of wet mantle wedge by self-promoting carbonation. Communications Earth & Environment 2, 151, doi: 10.1038/s43247-021-00224-5.

). In addition to mechanical processes, oxidative corrosion could promote such graphite degradation. However, it has not been fully clarified how the redox state of a fault temporally and spatially changes during the seismic cycle. For a more quantitative consideration, the kinetics of the reaction between oxidising fluid and various types of fault rocks and the lifetime of oxidising state of the fluid need to be clarified in future work, as well as how such fluid can affect the shear strength and frictional properties of the rock.

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Acknowledgments

We are grateful to Norifumi Abo (Central Institute of Isotope Science, Hokkaido University) for technical assistance. We also acknowledge two anonymous reviewers and editor Satish Myneni for their constructive comments, which greatly improved the manuscript. The analysers (Quantachrome Autosorb) are registered in the Open Facility system managed by the Global Facility Center, Creative Research Institution, Hokkaido University.

Editor: Satish Myneni

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References

Show in context

For example, some lithologies such as shales have been shown to undergo a variety of degradation on interaction with H₂O₂ (formation of cracks and voids, decomposition and dissolution of constituent materials, etc.), which results in modification of their hydromechanical properties at varying rates depending on temperature (Chen et al., 2017; Zhou et al., 2018; Yu et al., 2019).
View in article
Such oxidising fluid is thought to interact with Fe-bearing minerals as well as organic compounds (Chen et al., 2017; Zhou et al., 2018).
View in article

Croiset, E., Rice, S.F., Hanush, R.G. (2004) Hydrogen peroxide decomposition in supercritical water. Reactors, Kinetics, and Catalysis 43, 2343–2352.

Show in context

In the supercritical condition (T > 374 °C), the activation energy of the decomposition reaction can be higher (182 kJ mol⁻¹; Croiset et al., 2004), but the half-life is again very short (e.g., several seconds at 400 °C).
View in article

Eberl, D.D. (2003) User’s guide to RockJock-A program for determining quantitative mineralogy from powder X-ray diffraction data. USGS Open-file Report 03–78.

Show in context

Mineral compositions were analysed by X-ray diffraction analysis (XRD; MAC Science MX-Labo), and the obtained XRD patterns were used for quantitative analysis by RockJock software (Eberl, 2003).
View in article

Show in context

The basic schist samples (basic schist 1, basic schist 2, and basic schist 3) were taken from the chlorite, garnet, and albite–biotite zones of the Sanbagawa belt, respectively, which correspond to pressure-temperature (P-T) conditions ranging from greenschist to epidote-amphibolite facies (∼300 to ∼550 °C; Enami et al., 1994).
View in article

Show in context

ROS are also formed due to reaction with reactive secondary minerals and photochemistry in soils and sediments (e.g., Georgiou et al., 2015).
View in article

Show in context

The samples are sedimentary, metamorphic, and igneous rocks that may constitute plate boundaries at various depths in subduction zones (Hacker et al., 2003; Kimura et al., 2012; Kameda et al., 2017).
View in article

Show in context

Although the actual mechanism of H₂O₂ production from pulverised mineral surfaces is not completely understood, Hendrix et al. (2019) argued that Si−O· on a newly created mineral surface reacts with H₂O to generate H₂O₂ as follows:
Eq. 1
View in article
In addition, numerous studies have demonstrated that pulverisation of pure powders of minerals forming igneous rocks can produce oxidising compounds such as hydrogen peroxide (H₂O₂), superoxide (O₂·⁻), and hydroxy (·OH) radicals (Schoonen et al., 2006; Hurowitz et al., 2007; Hendrix et al., 2019), which are termed “reactive oxygen species” or “ROS”.
View in article

Show in context

The production of H₂ by the interaction of fluids and comminuted rocks has been demonstrated by laboratory experiments (Kita et al., 1982; Kameda et al., 2003; Hirose et al., 2011) and that associated with seismic activity has been observed by field survey (Wakita et al., 1980; Ito et al., 1999).
View in article

Hirose, T., Mizoguchi, K., Shimamoto, T. (2012) Wear processes in rocks at slow to high slip rates. Journal of Structural Geology 38, 102–116, doi: 10.1016/j.jsg.2011.12.007.

Show in context

Furthermore, larger slip events may also lead to greater amount of comminution (Scholz, 2002; Hirose et al., 2012), which would produce more H₂O₂.
View in article

Hochstrasser, G., Antonini, J.F. (1972) Surface states of pristine silica surfaces I. ESR studies of Es’ dangling bonds and of CO₂-adsorbed radicals. Surface Science 32, 644–664.

Show in context

Radical species such as Si· and SiO· are commonly created on such particles of silicate minerals owing to homolytic rupture of Si–O covalent bonds (Hochstrasser and Antonini, 1972; Narayanasamy and Kubicki, 2005).
View in article

Show in context

Hurowitz et al. (2007) conducted pulverisation experiments using various pure mineral types and found that H₂O₂ productivity depends on the crystallographic nature of silicate minerals, with productivity increasing with a decreasing number of corners shared between Si (Al) tetrahedra (here termed the “c” number; Fig. 2).
View in article
For example, tectosilicate minerals such as quartz and plagioclase have c = 4 and show the lowest H₂O₂ productivity of <1.0 nmol m⁻² of other types of silicate minerals with c < 4 (Hurowitz et al., 2007; Fig. 2).
View in article
Figure 2 presents the relationship between H₂O₂ productivity and c of the analysed rock samples, and shows that the data are broadly consistent with the results of Hurowitz et al. (2007).
View in article
Data and regression line from Hurowitz et al. (2007) are also shown.
View in article
In addition, numerous studies have demonstrated that pulverisation of pure powders of minerals forming igneous rocks can produce oxidising compounds such as hydrogen peroxide (H₂O₂), superoxide (O₂·⁻), and hydroxy (·OH) radicals (Schoonen et al., 2006; Hurowitz et al., 2007; Hendrix et al., 2019), which are termed “reactive oxygen species” or “ROS”.
View in article

Show in context

Kretz, R. (1996) Graphite deformation in marble and mylonitic marble, Grenville Province, Canadian Shield. Journal of Metamorphic Geology 14, 399–412.

Show in context

In natural examples, degradation or consumption of graphite has been observed in some fault zones (Nishiyama et al., 1990; Kretz, 1996; Nakamura et al., 2015), and the involvement of oxidising fluids in these processes has been suggested (Nishiyama, 1990; Okamoto et al., 2021).
View in article

Larsen, I.L., Hartmann, N.A., Wagner, J.J. (1973) Estimating precision for the method of standard additions. Analytical Chemistry 45, 1511–1513.

Show in context

Error bars for H₂O₂ productivity were estimated from the equation for the standard addition method (Larsen et al., 1973).
View in article

Show in context

Narayanasamy, J., Kubicki, J.D. (2005) Mechanism of Hydroxyl Radical Generation from a Silica Surface: Molecular Orbital Calculations. The Journal of Physical Chemistry B 109, 21796–21807.

Show in context

Nur, A., Booker, J.R. (1972) Aftershocks caused by pore fluid flow? Science 175, 885–887.

Show in context

Porewater diffusion is usually invoked as a reason for aftershock sequence (e.g., Nur and Booker, 1972), but only the physical aspect of water (i.e. fluid pressure) has been argued in these models.
View in article

Show in context

Sammis, C.G., Osborne, R.H., Anderson, J.L., Banerdt, M., White, P. (1986) Self-similar cataclasis in the formation of fault gouge. Pure and Applied Geophysics 124, 53–78.

Show in context

Frictional slip on a fault zone causes comminution and wearing of fault rocks, producing highly reactive fine particles (Sammis et al., 1986; Scholz, 2002).
View in article

Scholz, C.H. (2002) The mechanics of earthquake and faulting. Second Edition, Cambridge University Press, Cambridge.

Show in context

Furthermore, larger slip events may also lead to greater amount of comminution (Scholz, 2002; Hirose et al., 2012), which would produce more H₂O₂.
View in article
In general, an earthquake does not occur in isolation but occurs as part of a sequence controlled by physical processes such as stress perturbation (Scholz, 2002).
View in article
Frictional slip on a fault zone causes comminution and wearing of fault rocks, producing highly reactive fine particles (Sammis et al., 1986; Scholz, 2002).
View in article

Show in context

ROS are formed by human activities such as mining, which produces fine particles of rocks and minerals (Schoonen et al., 2006).
View in article
In addition, numerous studies have demonstrated that pulverisation of pure powders of minerals forming igneous rocks can produce oxidising compounds such as hydrogen peroxide (H₂O₂), superoxide (O₂·⁻), and hydroxy (·OH) radicals (Schoonen et al., 2006; Hurowitz et al., 2007; Hendrix et al., 2019), which are termed “reactive oxygen species” or “ROS”.
View in article

Takagi, J., Ishigure, K. (1985) Thermal decomposition of hydrogen peroxide and its effect on reactor water monitoring of boiling water reactors. Nuclear Science and Engineering 89, 177.

Show in context

The rate coefficient of the decomposition reaction is described as k = 6.4 × 10⁵ exp(−71 kJ mol⁻¹ / RT) s⁻¹ (Takagi and Ishigure, 1985).
View in article

Wakita, H., Nakamura, Y., Kita, I., Fujii, N., Notsu, K. (1980) Hydrogen release: New indicator of fault activity. Science 210, 188–190, doi: 10.1126/science.210.4466.188.

Show in context

Wang, X., Zhang, L. (2018) Green and facile production of high-quality graphene from graphite by the combination of hydroxyl radical and electrical exfoliation. RSC Advances 8, 40621.

Show in context

·OH oxidises even graphite (Wang and Zhang, 2018), a common product of the thermal maturation of organic compounds in metamorphic rocks, and may therefore degrade fault zones containing such minerals and materials.
View in article

Yu, W.G., Lei, J., Wang, T., Chen, W. (2019) H₂O₂-enhanced shale gas recovery under different thermal conditions. Energies 12, 2127, doi: 10.3390/en12112127.

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Zhou, Y., Lei, Y., Cheng, W., Yu, W. (2018) Enhance low temperature oxidization of shale gas recovery using hydrogen peroxide. Journal of Petroleum Science and Engineering 164, 523–530.

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