Tectonic stress chemistry- a possible perspective on focal mechanism of slow earthquakes

doi:10.7523/j.ucas.2024.010

Abstract

Abstract: Researches on the focal mechanism was mainly based on brittle deformation. However, high ratios of P-wave to S-wave velocity, anomalously high Poisson's ratios indicate that the source material of slow earthquakes is more viscous and more prone to plastic deformation. Traditional studies suggest that plastic deformation begins with dislocation, and is permanent. Therefore, the plastic strain energy cannot be released. However, it is maybe different when talked about on a microscopic molecular scale. The lithosphere is mainly constructed of silicate minerals, especially of tetracoordinated compounds with [SiO₄] tetrahedrons as fundamental units. That is, within minerals are chemical bonds binding various atoms together. Therefore, the dislocation mechanism of plastic deformation may first start with the change of chemical bonds, and then the chemical bonds begin to break off and rebonding, forming sub-grains and grain size reduction. Mechanochemical study shows that the mechanical force can directly act on the chemical bond via stretching and rotating, change the bond length, angle, and finally break off the chemical bond. Quantum chemical calculations on molecular fragments of the crystalline structure in coal indicate that the carbon bond breaks off at high energy levels, when the hydroxyl group of the 6-membered benzene ring falls off to form CO and 5-membered rings. During plastic deformation, the energy conversion may be work done from mechanical energy by external forces firstly to internal energy as atomic potential energy, and then plastic strain energy. However, not all atomic potential energy could transform into plastic strain energy for the reconstruction of the chemical bond may releases energy. As a result, a little energy may be released during the plastic deformation. Whether this is related to slow earthquakes is a scientific proposition worth exploring. It may be a possible way to explore the focal mechanism of slow earthquakes by using atomic scale quantum chemistry calculation to establish a finer energy change process of crystal plastic deformation and comparing the source parameters of slow earthquakes.

Key words: Slow earthquake, focal mechanism, microscopic mechanism of plastic deformation, plastic strain energy, tectonic stress chemistry

CLC Number:

P545

GUO Qianqian, SUN Jingxian, HOU Quanlin. Tectonic stress chemistry- a possible perspective on focal mechanism of slow earthquakes[J]. Journal of University of Chinese Academy of Sciences, DOI: 10.7523/j.ucas.2024.010.

References

[1] Sacks I S, Linde A T, Suyehiro S, et al.Slow earthquakes and stress redistribution[J]. Nature, 1978, 275(5681): 599-602. DOI: 10.1038/275599a0.
[2] Dragert G, Wang K L, James T S.A silent slip event on the deeper Cascadia subduction interface[J]. Science, 2001, 292(5521): 1525-1528. DOI: 10.1126/science.1060152.
[3] Ide S, Beroza G C, Shelly D R, et al.A scaling law for slow earthquakes[J]. Nature, 2007, 447(7140): 76-79. DOI: 10.1038/nature05780.
[4] Kawasaki I, Asai Y, Tamura Y, et al.The 1992 sanriku-oki, Japan, ultra-slow earthquake[J]. Journal of Physics of the Earth, 1995, 43(2): 105-116. DOI: 10.4294/jpe1952.43.105.
[5] Miller M M, Melbourne T, Johnson D J, et al.Periodic slow earthquakes from the Cascadia subduction zone[J]. Science, 2002, 295(5564): 2423. DOI: 10.1126/science.1071193.
[6] Nishikawa T, Ide S, Nishimura T.A review on slow earthquakes in the Japan Trench[J]. Progress in Earth and Planetary Science, 2023, 10(1): 1. DOI: 10.1186/s40645-022-00528-w.
[7] Shelly D R, Beroza G C, Ide S.Non-volcanic tremor and low-frequency earthquake swarms[J]. Nature, 2007, 446(7133): 305-307. DOI: 10.1038/nature05666.
[8] Ide S.A Brownian walk model for slow earthquakes[J]. Geophysical Research Letters, 2008, 35(17). DOI: 10.1029/2008gl034821.
[9] Ide S, Imanishi K, Yoshida Y, et al.Bridging the gap between seismically and geodetically detected slow earthquakes[J]. Geophysical Research Letters, 2008, 35(10). DOI: 10.1029/2008gl034014.
[10] Beroza G C, Ide S.Slow earthquakes and nonvolcanic tremor[J]. Annual Review of Earth and Planetary Sciences, 2011, 39: 271-296. DOI: 10.1146/annurev-earth-040809-152531.
[11] Gao X, Wang K L.Rheological separation of the megathrust seismogenic zone and episodic tremor and slip[J]. Nature, 2017, 543(7645): 416-419. DOI: 10.1038/nature21389.
[12] Thomas A M, Beroza G C, Shelly D R.Constraints on the source parameters of low-frequency earthquakes on the San Andreas Fault[J]. Geophysical Research Letters, 2016, 43(4): 1464-1471. DOI: 10.1002/2015gl067173.
[13] Wei X T, Xu J K, Liu Y X, et al.The slow self-arresting nature of low-frequency earthquakes[J]. Nature Communications, 2021, 12(1): 5464. DOI: 10.1038/s41467-021-25823-w.
[14] Kirkpatrick J D, Fagereng Å, Shelly D R.Geological constraints on the mechanisms of slow earthquakes[J]. Nature Reviews Earth & Environment, 2021, 2(4): 285-301. DOI: 10.1038/s43017-021-00148-w.
[15] Wang K L, Tréhu A M.Invited review paper: Some outstanding issues in the study of great megathrust earthquakes—The Cascadia example[J]. Journal of Geodynamics, 2016, 98: 1-18. DOI: 10.1016/j.jog.2016.03.010.
[16] Shelly D R, Beroza G C, Ide S, et al.Low-frequency earthquakes in Shikoku, Japan, and their relationship to episodic tremor and slip[J]. Nature, 2006, 442(7099): 188-191. DOI: 10.1038/nature04931.
[17] Obara K.Inhomogeneous distribution of deep slow earthquake activity along the strike of the subducting Philippine Sea Plate[J]. Gondwana Research, 2009, 16(3/4): 512-526. DOI: 10.1016/j.gr.2009.04.011.
[18] Bell R, Sutherland R, Barker D H N, et al. Seismic reflection character of the Hikurangi subduction interface, New Zealand, in the region of repeated Gisborne slow slip events[J]. Geophysical Journal International, 2010, 180(1): 34-48. DOI: 10.1111/j.1365-246X.2009.04401.x.
[19] Shelly D R, Hardebeck J L.Precise tremor source locations and amplitude variations along the lower-crustal central San Andreas Fault[J]. Geophysical Research Letters, 2010, 37(14). DOI: 10.1029/2010gl043672.
[20] Kodaira S, Iidaka T, Kato A, et al.High pore fluid pressure may cause silent slip in the Nankai Trough[J]. Science, 2004, 304(5675): 1295-1298. DOI: 10.1126/science.1096535.
[21] 张龙, 江在森, 武艳强. 速度-状态摩擦本构定律及其在地震断层中的应用研究进展[J]. 地球物理学进展, 2013, 28(5): 2352-2362. DOI: 10.6038/pg20130517.
[22] 杨又陵, 赵根模, 高国英, 等. 2001年11月14日昆仑山口西M 8.1地震前的缓慢地震事件[J]. 国际地震动态, 2003(9): 1-4. DOI: 10.3969/j.issn.0253-4975.2003.09.001.
[23] Scholz C H.The brittle-plastic transition and the depth of seismic faulting[J]. Geologische Rundschau, 1988, 77(1): 319-328. DOI: 10.1007/BF01848693.
[24] Leeman J R, Saffer D M, Scuderi M M, et al.Laboratory observations of slow earthquakes and the spectrum of tectonic fault slip modes[J]. Nature Communications, 2016, 7: 11104. DOI: 10.1038/ncomms11104.
[25] Ikari M J, Marone C, Saffer D M, et al.Slip weakening as a mechanism for slow earthquakes[J]. Nature Geoscience, 2013, 6: 468-472. DOI: 10.1038/ngeo1818.
[26] Okazaki K, Katayama I.Slow stick slip of antigorite serpentinite under hydrothermal conditions as a possible mechanism for slow earthquakes[J]. Geophysical Research Letters, 2015, 42(4): 1099-1104. DOI: 10.1002/2014gl062735.
[27] Ikari M J, Kopf A J.Seismic potential of weak, near-surface faults revealed at plate tectonic slip rates[J]. Science Advances, 2017, 3(11): e1701269. DOI: 10.1126/sciadv.1701269.
[28] 刘世民, 张雷, 何昌荣. 高压流体条件下叶蛇纹石摩擦特性及其对俯冲带慢滑移事件的启示[J]. 地球物理学报, 2023, 66(4): 1334-1347. DOI: 10.6038/cjg2022Q0290.
[29] 姜辉. 俯冲带断层粘滑运动机制数值模拟研究: 以日本俯冲带为例[D]. 北京: 中国地震局地质研究所, 2012.
[30] Li D, Liu Y J.Modeling slow-slip segmentation in Cascadia subduction zone constrained by tremor locations and gravity anomalies[J]. Journal of Geophysical Research: Solid Earth, 2017, 122(4): 3138-3157. DOI: 10.1002/2016jb013778.
[31] Li H T, Wei M, Li D, et al.Segmentation of slow slip events in south central Alaska possibly controlled by a subducted oceanic plateau[J]. Journal of Geophysical Research: Solid Earth, 2018, 123(1): 418-436. DOI: 10.1002/2017jb014911.
[32] 苟涛. 俯冲带深部结构、变形与孕震环境研究[D]. 南京: 南京大学, 2020.
[33] 魏雪婷. 震源动力学破裂相图与慢地震理论模型研究[D]. 合肥: 中国科学技术大学, 2022.
[34] 李昊天, 周仕勇. 断层几何形态对阿拉斯加中南部俯冲带慢滑移特征的影响[J]. 地震学报, 2019, 41(6): 681-694. DOI: 10.11939/jass.20190102.
[35] Frenkel J, Kontorova T.On the theory of plastic deformation and twinning[J]. zh.eksp.teor.fiz, 1939, 1: 137-149. DOI: 10.1104/pp.105.060269.
[36] Gershenzon N I, Bambakidis G, Hauser E, et al.Episodic tremors and slip in Cascadia in the framework of the Frenkel-Kontorova model[J]. Geophysical Research Letters, 2011, 38(1). DOI: 10.1029/2010gl045225.
[37] Seidel C A M, Kühnemuth R. Molecules under pressure[J]. Nature Nanotechnology, 2014, 9: 164-165. DOI: 10.1038/nnano.2014.46.
[38] 侯泉林. 高等构造地质学-第四卷-知识综合与运用[M]. 北京: 科学出版社, 2021: 1-338.
[39] Akbulatov S, Tian Y C, Boulatov R.Force-reactivity property of a single monomer is sufficient to predict the micromechanical behavior of its polymer[J]. Journal of the American Chemical Society, 2012, 134(18): 7620-7623. DOI: 10.1021/ja301928d.
[40] Beyer M K, Clausen-Schaumann H.Mechanochemistry: The mechanical activation of covalent bonds[J]. Chemical Reviews, 2005, 105(8): 2921-2948. DOI: 10.1021/cr030697h.
[41] Brantley J N, Wiggins K M, Bielawski C W.RETRACTED: Unclicking the click: Mechanically facilitated 1,3-dipolar cycloreversions[J]. Science, 2011, 333(6049): 1606-1609. DOI: 10.1126/science.1207934.
[42] Craig S L.Mechanochemistry: A tour of force[J]. Nature, 2012, 487(7406): 176-177. DOI: 10.1038/487176a.
[43] Davis D A, Hamilton A, Yang J L, et al.Force-induced activation of covalent bonds in mechanoresponsive polymeric materials[J]. Nature, 2009, 459: 68-72. DOI: 10.1038/nature07970.
[44] Duwez A S, Cuenot S, Jérôme C, et al.Mechanochemistry: Targeted delivery of single molecules[J]. Nature Nanotechnology, 2006, 1(2): 122-125. DOI: 10.1038/nnano.2006.92.
[45] Haseen S, Kroll P.Paving the way for cristobalite TiO₂ and GeO₂ attainable under moderate tensile stress: A DFT study of transformation paths and activation barriers in cristobalite-rutile transformations of MO₂ (M=Si, Ge, Ti)[J]. Computational Materials Science, 2019, 170: 109170. DOI: 10.1016/j.commatsci.2019.109170.
[46] Hickenboth C R, Moore J S, White S R, et al.Biasing reaction pathways with mechanical force[J]. Nature, 2007, 446(7134): 423-427. DOI: 10.1038/nature05681.
[47] Krishnan B P, Sureshan K M.A spontaneous single-crystal-to-single-crystal polymorphic transition involving major packing changes[J]. Journal of the American Chemical Society, 2015, 137(4): 1692-1696. DOI: 10.1021/ja512697g.
[48] Wang J P, Kouznetsova T B, Craig S L.Reactivity and mechanism of a mechanically activated anti-woodward-hoffmann-DePuy Reaction[J]. Journal of the American Chemical Society, 2015, 137(36): 11554-11557. DOI: 10.1021/jacs.5b06168.
[49] Panda M K, Runčevski T, Husain A, et al.Perpetually self-propelling chiral single crystals[J]. Journal of the American Chemical Society, 2015, 137(5): 1895-1902. DOI: 10.1021/ja5111927.
[50] 徐秉业, 刘信声. 应用弹塑性力学[M]. 北京: 清华大学出版社, 1995.
[51] Cheng N N, Pan J N, Shi M Y, et al.Using Raman spectroscopy to evaluate coal maturity: The problem[J]. Fuel, 2022, 312: 122811. DOI: 10.1016/j.fuel.2021.122811.
[52] Han Y Z, Xu R T, Hou Q L, et al.Deformation mechanisms and macromolecular structure response of anthracite under different stress[J]. Energy & Fuels, 2016, 30(2): 975-983. DOI: 10.1021/acs.energyfuels.5b02837.
[53] Han Y Z, Wang J, Dong Y J, et al.The role of structure defects in the deformation of anthracite and their influence on the macromolecular structure[J]. Fuel, 2017, 206: 1-9. DOI: 10.1016/j.fuel.2017.05.085.
[54] Hou Q L, Han Y Z, Wang J, et al.The impacts of stress on the chemical structure of coals: A mini-review based on the recent development of mechanochemistry[J]. Science Bulletin, 2017, 62(13): 965-970. DOI: 10.1016/j.scib.2017.06.004.
[55] Wang J, Han Y Z, Chen B Z, et al.Mechanisms of methane generation from anthracite at low temperatures: Insights from quantum chemistry calculations[J]. International Journal of Hydrogen Energy, 2017, 42(30): 18922-18929. DOI: 10.1016/j.ijhydene.2017.06.090.
[56] Wang J, Guo G J, Han Y Z, et al.Mechanolysis mechanisms of the fused aromatic rings of anthracite coal under shear stress[J]. Fuel, 2019, 253: 1247-1255. DOI: 10.1016/j.fuel.2019.05.117.
[57] Wang J, Hou Q L, Zeng F G, et al.Stress sensitivity for the occurrence of coalbed gas outbursts: A reactive force field molecular dynamics study[J]. Energy & Fuels, 2021, 35(7): 5801-5807. DOI: 10.1021/ACS.ENERGYFUELS.0C04201.
[58] 徐容婷, 李会军, 侯泉林, 等. 不同变形机制对无烟煤化学结构的影响[J]. 中国科学: 地球科学, 2015, 45(1): 34-42. DOI: 10.1007/s11430-014-4998-x.
[59] Xu R T, Li H J, Guo C C, et al.The mechanisms of gas generation during coal deformation: Preliminary observations[J]. Fuel, 2014, 117: 326-330. DOI: 10.1016/j.fuel.2013.09.035.
[60] Yang G, Li L H, Lee W B, et al.Structure of graphene and its disorders: A review[J]. Science and Technology of Advanced Materials, 2018, 19(1): 613-648. DOI: 10.1080/14686996.2018.1494493.
[61] He C R, Zhang L, Liu P X, et al.Characterizing the final stage of simulated earthquake nucleation governed by rate-and-state fault friction[J]. Journal of Geophysical Research: Solid Earth, 2023, 128(5). DOI: 10.1029/2023JB026422.
[62] 高玲举, 张健, 吴时国. 马里亚纳海沟Challenger Deep的岩石圈流变结构与动力学分析[J]. 中国科学院大学学报, 2017, 34(3): 380-388. DOI: 10.7523/j.issn.2095-6134.2017.03.012.
[63] 刘俊来. 大陆中部地壳应变局部化与应变弱化[J]. 岩石学报, 2017, 33(6): 1653-1666.
[64] Ruina A.Slip instability and state variable friction laws[J]. Journal of Geophysical Research: Solid Earth, 1983, 88(B12): 10359-10370. DOI: 10.1029/jb088ib12p10359.
[65] Shibazaki B, Obara K, Matsuzawa T, et al.Modeling of slow slip events along the deep subduction zone in the Kii Peninsula and Tokai regions, southwest Japan[J]. Journal of Geophysical Research (Solid Earth), 2012, 117(B6): B06311. DOI: 10.1029/2011JB009083.
[66] 张雷. 龙门山断裂带断层岩在水热条件下的摩擦滑动特性实验研究[D]. 北京: 中国地震局地质研究所, 2013.
[67] 刘旭耀, 胡才博, 石耀霖. 基于实验数据的岩石变形过程中温度场演化的数值模拟[J]. 中国科学院大学学报, 2015, 32(5): 644-651. DOI: 10.7523/j.issn.2095-6134.2015.05.010.
[68] 魏炜, 余新刚. 锂对铁素体拉伸力学行为影响的分子动力学研究[J]. 中国科学院大学学报, 2022, 39(1): 13-20. DOI: 10.7523/j.ucas.2020.0024.
[69] 夏骏. 氧化石墨烯层状材料界面交联的力化学机理研究[D]. 合肥: 中国科学技术大学, 2020.
[70] 方武章, 张礼川, 闫清波, 等. 应变对硒化锡和硫化锡拉胀材料力学性质和能带结构的调控[J]. 中国科学院大学学报, 2017, 34(1): 8-14. DOI: 10.7523/j.issn.2095-6134.2017.01.002.
[71] 刘松畅, 余新刚. 单晶钨辐照损伤的分子动力学研究[J/OL]. (2023-01-09)[2023-12-25].中国科学院大学学报, 2023. DOI: 10.7523/j.ucas.2022.087.
[72] 吴伟, 余新刚.Ar原子与石墨片层相互作用的分子动力学研究*[J/OL].(2023-05-23)[2023-12-25]中国科学院大学学报, 2023. DOI: 10.7523/j.ucas.2023.064.