GEOCHEMICAL CHARACTERIZATION OF FAULT GAS IN MACRO-SEISMIC INTENSITY AND AFTERSHOCK DISTRIBUTION OF JINGHE MS6.6 EARTHQUAKE ON AUGUST 9, 2017

doi:10.3969/j.issn.0253-4967.2022.05.009

Abstract

Abstract:

An M_S6.6 earthquake struck Jinghe County, Boltala Prefecture, Xinjiang at 7:27:52 am on August 9, 2017, with the epicenter located in the eastern section of the Cusongmuqike piedmont fault. In order to study the activity characteristics of the faults around Jinghe after the M_S6.6 earthquake, the field survey and selection of the Cusongmuqike piedmont fault and the Jinghe section of the Bolokenu-Aqikekuduke Fault were carried out from October 18 to November 3, 2017. Mobile monitoring of soil gas geochemistry was carried out at 191 survey points respectively on 12 survey lines of Cusongmuqike piedmont fault and two survey lines on the Jinghe section of Bolokenu-Aqikekuduke Fault, and the concentrations of Rn, H₂ and CO₂ emitted from soil across the fault were observed. The results show that: 1)The concentrations of soil gases Rn, CO₂ and H₂ were consistent, and the high values appeared near the faults, with obvious single-peak characteristics. 2)The concentration of Rn, CO₂ and H₂ increased gradually from west to east and reached the highest value near the main shock and aftershock areas, and the concentration of soil gas reached the lowest value in the Jinghe section of the Bolokenu-Aqikekuduke Fault. 3)There is a good consistency between Rn and CO₂ concentration anomaly intensity, and the distribution regions of both are basically opposite to H₂ concentration anomaly intensity. The high values of soil gas Rn and CO₂ anomaly intensity mainly concentrated in the west of the epicenter area of Jinghe M_S6.6 earthquake(line 7, 8, 9 and 10 area), which was the aftershock concentration area, and the lowest value of H₂ anomaly intensity appeared in this area. Reason may be that the aftershock concentration area was also the fault activity enhancement area, with the occurrence of aftershocks, stress increased, the permeability of rock decreased, and the gas in fault pores released sustainedly, causing the concentration change of gases emitted from fault. Since Rn cannot participate in the migration activities such as diffusion and convection, it was brought to the surface from deep underground carried by CO₂, this could explain the abnormal synchronization of Rn and CO₂. Hydrogen, as the element with the smallest particle size, lightest mass, fastest migration speed and strongest penetration, mainly comes from the trapped hydrogen in the pores and fissures of deep rock. After the earthquake, the pores in the rock were damaged, and hydrogen rapidly emitted to the shallow part or atmosphere. On the one hand, with the occurrence of aftershocks, the amount of H₂ from shallow gas reservoirs was decreasing. On the other hand, the generation of H₂ produced by chemical reactions in rocks decreased with the decrease of fault activity. The measurement was done more than 70 days after the occurrence of the main shock, during which the activity of strong aftershocks tended to end and the activity of the fault also weakened. 4)Concentrations of soil gas Rn, CO₂ and H₂ have a good consistency with the distribution of aftershocks and the macroseismic intensity, so, carrying out in a timely manner the soil gas geochemical observation is an effective means and method for earthquake trend judgment, soil gas geochemical observation in and around the earthquake area is a kind of effective means and methods for earthquake trend judgement, and the cross-fault soil gas concentrations can also be used as an important supplement to the macroseismic intensity evaluation.

Key words: Jinghe M_S6.6 earthquake, cross-fault soil gas, geochemistry, gas concentration

摘要：

2017年8月9日7时27分52秒, 新疆博尔塔拉州精河县发生 M_S6.6 地震, 震中位于库松木契克山前断裂的东段。为研究精河 M_S6.6 地震后其周边断裂的活动特征, 对库松木契克山前断裂及博罗科努-阿其克库都克断裂精河段开展跨断层土壤逸出气体Rn、 H₂、 CO₂的浓度测量。结果表明: 1)土壤气体Rn、 CO₂和H₂的浓度有较好的一致性, 高值出现在断层附近, 多呈现明显的单峰特征。2)Rn、 CO₂和H₂浓度在空间上有明显的分段特征, 从西向东浓度值逐渐增大, 主震和余震集中区附近达到最高值, 博罗科努-阿其克库都克断裂精河段的土壤气浓度达到最低值。3)Rn、 CO₂的浓度异常强度有很好的一致性, 两者的高、低值分布区域与H₂基本相反。余震集中的区域也是断层活动增强的区域, 随着余震的发生, 应力增加, 岩石的渗透性减小, 使得不能参与扩散和对流等迁移活动的Rn被CO₂从地下深部携带至地表, 这能解释Rn和CO₂出现同步异常的原因; H₂主要被封存于深部的岩石孔隙和裂隙中, 地震发生后, 岩石中的孔隙受到破坏, H₂迅速逃逸到浅部或大气中。一方面, 随着余震的发生来自浅部气藏的H₂量越来越少; 另一方面, 岩石中因化学反应产生的H₂生成量随断层活动性的降低而下降。4)土壤气Rn、 CO₂和H₂的浓度大小与余震分布和地震宏观烈度有较好的一致性, 及时在震区和外围区域开展土壤气体地球化学观测是震后趋势判定的一种有效手段和方法, 也可把跨断层土壤气体的浓度作为地震宏观烈度评定的重要补充资料。

关键词: 精河6.6级地震, 跨断层土壤气体, 地球化学, 气体浓度

ZHU Cheng-ying, YAN Wei, MA Rong, LI Zhi-hai, WANG Cheng-guo, HUANG Jian-ming, ZHOU Xiao-cheng. GEOCHEMICAL CHARACTERIZATION OF FAULT GAS IN MACRO-SEISMIC INTENSITY AND AFTERSHOCK DISTRIBUTION OF JINGHE M_S6.6 EARTHQUAKE ON AUGUST 9, 2017[J]. SEISMOLOGY AND GEOLOGY, 2022, 44(5): 1225-1239.

朱成英, 闫玮, 麻荣, 李志海, 汪成国, 黄建明, 周晓成. 2017年8月9日精河M_S6.6地震宏观烈度及其余震分布的断层气体地球化学表征[J]. 地震地质, 2022, 44(5): 1225-1239.

Figures/Tables 6

References 29

[1]	白兰淑, 刘杰, 张莹莹, 等. 2017. 2017年精河6.6级地震余震序列重新定位和发震构造[J]. 中国地震, 33(4): 703-711.
	BAI Lan-shu, LIU Jie, ZHANG Ying-ying, et al. 2017. Relocation of the 2017 M_S6.6 Jinghe, Xinjiang earthquake sequence and its seismogenic structure[J]. Earthquake Research in China, 33(4): 703-711. (in Chinese)
[2]	陈建波, 沈军, 李军, 等. 2007. 北天山西段库松木楔克山山前断层新活动特征初探[J]. 西北地震学报, 29(4): 335-340.
	CHEN Jian-bo, SHEN Jun, LI Jun, et al. 2007. Preliminary study on new active characteristics of Kusongmuxieke mountain front fault in the west segment of North Tianshan[J]. Northwestern Seismological Journal, 29(4): 335-340. (in Chinese)
[3]	陈建波, 谭明, 吴国栋, 等. 2012a. 2011年10月16日新疆精河县5.0级地震震害特征及发震构造[J]. 内陆地震, 26(3): 233-241.
	CHEN Jian-bo, TAN Ming, WU Guo-dong, et al. 2012a. The characteristic of seismic hazard and seismogenic structure of Jinghe earthquake with M_S5.0 Xinjiang on Oct 16^th, 2011[J]. Inland Earthquake, 26(3): 233-241. (in Chinese)
[4]	陈建波, 谭明, 吴国栋, 等. 2012b. 2011年10月16日新疆精河县5.0级地震震害特征及原因[J]. 震灾防御技术, 7(2): 164-172.
	CHEN Jian-bo, TAN Ming, WU Guo-dong, et al. 2012b. The seismic damage characteristic and the cause of the Jinghe M5.0 earthquake in Xinjiang on Oct. 16, 2011[J]. Technology for Earthquake Disaster Prevention, 7(2): 164-172. (in Chinese)
[5]	谷元珠, 林元武, 张培仁. 2001. 气体地球化学方法在震后趋势判断中的应用[J]. 地震, 21(2): 101-104.
	GU Yuan-zhu, LIN Yuan-wu, ZHANG Pei-ren. 2001. Application of gas geochemical method to prediction of seismic trend after mainshock[J]. Earthquake, 21(2): 101-104. (in Chinese)
[6]	姜祥华, 韩颜颜, 杨文, 等. 2017. 2017年精河 M_S6.6 地震序列及震源特征初步分析[J]. 中国地震, 33(4): 682-693.
	JIANG Xiang-hua, HAN Yan-yan, YANG Wen, et al. 2017. Preliminary analysis of the 2017 Jinghe M_S6.6 earthquake sequence and its seismic source characteristics[J]. Earthquake Research in China, 33(4): 682-693. (in Chinese)
[7]	李营, 杜建国, 王富宽, 等. 2009. 延怀盆地土壤气体地球化学特征[J]. 地震学报, 31(1): 82-91.
	LI Ying, DU Jian-guo, WANG Fu-kuan, et al. 2009. Geochemical characteristics of soil gas in Yanqing-Huailai Basin, North China[J]. Acta Seismologica Sinica, 31(1): 82-91. (in Chinese)
[8]	林元武, 刘五洲, 王基华, 等. 1988. 张北-尚义地震现场CO₂测量与震后趋势判断[J]. 地震地质, 20(2): 117-121.
	LIN Yuan-wu, LIU Wu-zhou, WANG Ji-hua, et al. 1988. Observation of CO₂ in the field of Zhangbei-Shangyi earthquake and prediction of seismic trend after main shock[J]. Seismology and Geology, 20(2): 117-121. (in Chinese)
[9]	刘兆才, 万永革, 黄骥超, 等. 2019. 2017年精河 M_S6.6 地震邻区构造应力场特征与发震断裂性质的厘定[J]. 地球物理学报, 62(4): 1336-1348.
	LIU Zhao-cai, WAN Yong-ge, HUANG Ji-chao, et al. 2019. The tectonic field adjacent to the source of the 2017 Jinghe M_S6.6 earthquake and slip property of its seismogenic fault[J]. Chinese Journal of Geophysics, 62(4): 1336-1348. (in Chinese)
[10]	上官志冠, 武成智. 2008. 中国休眠火山区岩浆来源气体地球化学特征[J]. 岩石学报, 24(11): 2638-2646.
	SHANGGUAN Zhi-guan, WU Cheng-zhi. 2008. Geochemical features of magmatic gases in the regions of dormant volcanoes in China[J]. Acta Petrologica Sinica, 24(11): 2638-2646. (in Chinese)
[11]	汪成民, 李宣瑚. 1991a. 我国断层气测量在地震科学研究中的应用现状[J]. 中国地震, 7(2): 19-30.
	WANG Cheng-min, LI Xuan-hu. 1991a. Applications of fracture-gas measurement to the earthquake studies in China[J]. Earthquake Research in China, 7(2): 19-30. (in Chinese)
[12]	汪成民, 李宣瑚, 魏柏林. 1991b. 断层气测量在地震科学中的应用[M]. 北京: 地震出版社.
	WANG Cheng-min, LI Xuan-hu, WEI Bo-lin. 1991b. Application of Fault Gas Measurement in Earthquake Science[M]. Seismological Press, Beijing. (in Chinese)
[13]	周广法, 曾现虎, 吴元伟. 2013. 气体地球化学的研究现状与研究进展[J]. 科技风, 12: 239. doi: 10.19392/j.cnki.1671-7341.2013.12.204. DOI
	ZHOU Guang-fa, ZENG Xian-hu, WU Yuan-wei. 2013. Research status and progress of gas geochemistry[J]. Technology Wind, 12: 239. (in Chinese)
[14]	周晓成, 杜建国, 王传远, 等. 2007. 西藏拉萨市土壤气中氡、汞环境地球化学特征[J]. 环境科学, 28(3): 659-663.
	ZHOU Xiao-cheng, DU Jian-guo, WANG Chuan-yuan, et al. 2007. Geochemical characteristics of radon and mercury in soil gas in Lhasa, Tibet, China[J]. Environmental Science, 28(3): 659-663. (in Chinese)
[15]	周晓成, 石宏宇, 陈超, 等. 2017. 汶川 M_S8.0 地震破裂带土壤气中H₂浓度时空变化[J]. 地球科学进展, 32(8): 818-827. doi: 10.11867/j.issn.1001-8166.2017.08.0818. DOI
	ZHOU Xiao-cheng, SHI Hong-yu, CHEN Chao, et al. 2017. Spatial-temporal variation of H₂ concentration in soil gas in the seismic fault zone produced by the Wenchuan M_S8.0 earthquake[J]. Advances in Earth Science, 32(8): 818-827. (in Chinese)
[16]	周晓成, 王传远, 柴炽章, 等. 2011. 海原断裂带东南段土壤气体地球化学特征[J]. 地震地质, 33(1): 123-132. doi: 10.3969/j.issn.0253-4967.2011.01.012. DOI
	ZHOU Xiao-cheng, WANG Chuan-yuan, CHAI Chi-zhang, et al. 2011. The geochemical characteristics of soil gas in the southeastern part of Haiyuan Fault[J]. Seismology and Geology, 33(1): 123-132. (in Chinese)
[17]	朱宏任, 汪成民, 万登堡, 等. 1991. 地震烈度的气体地球化学标度初探[J]. 中国地震, 7(1): 59-64.
	ZHU Hong-ren, WANG Cheng-min, WAN Deng-bao, et al. 1991. A preliminary study on the scale of gaseous geochemistry for determining seismic intensity[J]. Earthquake Research in China, 7(1): 59-64. (in Chinese)
[18]	Aswal S, Kandari T, Sahoo B K, et al. 2016. Emission of soil gas radon concentration around main central thrust in Ukhimath(Rudraprayag)region of Garhwal Himalaya[J]. Radiation Protection Dosimetry, 171(2): 243-247. doi: 10.1093/rpd/ncw067. DOI URL
[19]	Bhongsuwan T, Pisapak P, Dürrast H. 2011. Result of alpha track detection of radon in soil gas in the Khlong Marui fault zone, southern Thailand: A possible earthquake precursor[J]. Songklanakarin Journal of Science and Technology, 33(5): 609-616.
[20]	Ciotoli G, Guerra M, Lombardi S, et al. 1998. Soil gas survey for tracing seismogenic faults: A case study in the Fucino Basin, central Italy[J]. Journal of Geophysical Research, 103(B10): 23781-23794. DOI URL
[21]	Dueñas C, Fernandez M C. 1988. Temporal variations in soil gas radon: Any possible relation to earthquakes?[J]. Tectonophysics, 152(1-2): 137-145. DOI URL
[22]	Fu C C, Yang T F, Chen C H, et al. 2017. Spatial and temporal anomalies of soil gas in northern Taiwan and its tectonic and seismic implications[J]. Journal of Asian Earth Sciences, 149: 64-77. DOI URL
[23]	Georgy C, Rafael Z, Ivan B. 2015. Radon monitoring in groundwater and soil gas of Sakhalin Island[J]. Journal of Geoscience and Environment Protection, 3: 48-53. doi: 10.4236/gep.2015.35006. DOI URL
[24]	İnzns Ertekin K, Seyis C, et al. 2010. Multi-disciplinary earthquake researches in western Turkey: Hints to select sites to study geochemical transients associated to seismicity[J]. Acta Geophysica, 58(5): 767-813. doi: 10.2478/s11600-010-0016-7. DOI
[25]	Morita M, Mori T, Yokoo A, et al. 2019. Continuous monitoring of soil CO₂ flux at Aso volcano, Japan: The influence of environmental parameters on diffuse degassing[J]. Earth Planets and Space, 71:1. doi:10.1186/s40623-018-0980-8. DOI URL
[26]	Ring U, Uysal I T, Yüce G, et al. 2016. Recent mantle degassing recorded by carbonic spring deposits along sinistral strike-slip faults, south-central Australia[J]. Earth &Planetary Science Letters, 454: 304-318. doi: 10.1016/j.epsl.2016.09.017. DOI
[27]	Sciarra A, Mazzini A, Inguaggiato S, et al. 2018. Radon and carbon gas anomalies along the Watukosek Fault System and Lusi mud eruption, Indonesia[J]. Marine & Petroleum Geology, 90:70-90. doi: 10.1016/j.marpetgeo.2017.09.031. DOI
[28]	Vaupotič J, Riggio A, Santulin M, et al. 2010. A radon anomaly in soil gas at Cazzaso, NE Italy, as a precursor of an M_L=5.1 earthquake[J]. Nukleonika, 55(4): 507-511.
[29]	Yüce G, Fu C C, D'Alessandro W, et al. 2017. Geochemical characteristics of soil radon and carbon dioxide within the Dead Sea Fault and Karasu Fault in the Amik Basin(Hatay), Turkey[J]. Chemical Geology, 469:129-146. doi: 10.1016/j.chemgeo.2017.01.003. DOI

测线/测点	Rn/Bq·m^-3		CO₂/%		H₂/ppm
	范围	平均值	范围	平均值	范围	平均值
1/12	3 300~8 610	6 089	0.035~0.064	0.045	53.11~199.7	95.62
2/12	2 130~13 900	6 069	0.036~0.088	0.048	7.79~117.7	47.0
3/13	3 530~6 410	5 001	0.043~0.068	0.056	12.26~129.3	46.46
4/12	1 020~9 770	5 302	0.037~0.057	0.045	16.34~111.7	45.80
5/14	2 480~9 820	5 339	0.042~0.114	0.073	14.89~177.9	74.78
6/18	2 780~6 840	4 879	0.034~0.054	0.045	12.35~320.7	90.21
7/12	2 880~13 500	5 223	0.044~0.099	0.062	19.82~342	128.21
8/12	817~8 070	1 249	0.052~0.15	0.10	12.83~104.7	46.18
9/16	2 900~10 300	6 365	0.035~0.064	0.046	5.25~91.73	31.91
10/15	1 770~8 600	4 413	0.05~0.105	0.067	20.94~145.4	65.22
11/15	2 600~7 830	4 983	0.045~0.095	0.073	11.58~133.3	54.22
12/13	2 580~5 350	3 965	0.038~0.06	0.044	8.03~146.6	29.49
13/14	1 760~4 360	3 401	0.032~0.052	0.039	9.04~240.3	45.77
14/13	1 960~5 430	3 188	0.037~0.051	0.042	6.48~27.8	13.42

测线/测点	Rn/Bq·m^-3		CO₂/%		H₂/ppm
	范围	平均值	范围	平均值	范围	平均值
1/12	3 300~8 610	6 089	0.035~0.064	0.045	53.11~199.7	95.62
2/12	2 130~13 900	6 069	0.036~0.088	0.048	7.79~117.7	47.0
3/13	3 530~6 410	5 001	0.043~0.068	0.056	12.26~129.3	46.46
4/12	1 020~9 770	5 302	0.037~0.057	0.045	16.34~111.7	45.80
5/14	2 480~9 820	5 339	0.042~0.114	0.073	14.89~177.9	74.78
6/18	2 780~6 840	4 879	0.034~0.054	0.045	12.35~320.7	90.21
7/12	2 880~13 500	5 223	0.044~0.099	0.062	19.82~342	128.21
8/12	817~8 070	1 249	0.052~0.15	0.10	12.83~104.7	46.18
9/16	2 900~10 300	6 365	0.035~0.064	0.046	5.25~91.73	31.91
10/15	1 770~8 600	4 413	0.05~0.105	0.067	20.94~145.4	65.22
11/15	2 600~7 830	4 983	0.045~0.095	0.073	11.58~133.3	54.22
12/13	2 580~5 350	3 965	0.038~0.06	0.044	8.03~146.6	29.49
13/14	1 760~4 360	3 401	0.032~0.052	0.039	9.04~240.3	45.77
14/13	1 960~5 430	3 188	0.037~0.051	0.042	6.48~27.8	13.42