CRUSTAL S-WAVE VELOCITY STRUCTURE BENEATH THE XIAO-JIANG FAULT ZONE AND ADJACENT REGIONS REVEALED BY TWO-STEP INVERSION METHOD OF RECEIVER FUNCTIONS

doi:10.3969/j.issn.0253-4967.2023.01.011

Abstract

Abstract:

In the past few decades, a large number of geophysical explorations were carried out in the Xiaojiang fault zone and adjacent areas, mainly including GPS, seismic geology, fluid geochemistry, seismicity, historical earthquakes and coseismic displacement of large earthquakes, etc. The results of these studies helped us have a better understanding of the fault structure characteristics, movement attributes, seismogenic environment and dynamic mechanism of the Xiaojiang fault zone. In terms of deep structure, the existing researches are limited by factors such as the density of observation stations, and most studies focused on the structural background on the regional scale, and few are specifically on this fault zone. The implementation of Phase I of the China Earthquake Science Array(ChinArray)detection project provides a good data basis for the study of the fault structure in Yunnan. It is of great practical significance for earthquake prevention and disaster mitigation to carry out deep structural detection of the Xiaojiang fault zone and clarify the fine crustal structure of the fault and its adjacent areas.

S-wave velocity is an important parameter to determine the crustal structure, physical state difference and tectonic evolution process. Extracting the P-wave receiver function from teleseismic body-wave waveform data and inverting it is one of the important methods to obtain the crustal S-wave velocity structure at present. The traditional receiver function S-wave velocity structure inversion relies heavily on the selection of the initial model, which results in strong non-uniqueness inversion results. The two-step inversion method, which takes into account the low and high frequency receiver functions at the same time, effectively suppresses the dependence of the inversion process on the initial model, and improves the reliability of the inversion results.

Based on the three-component waveform data of 238 teleseismic events with epicentral distances ranging from 30°~90° and magnitude M≥5.8 recorded by 48 broadband seismic stations in the Xiaojiang fault zone and adjacent areas from September 2, 2011 to January 16, 2014, this paper calculates the low-frequency(α=1.0)and high-frequency(α=2.5)radial P receiver functions, respectively. Then, on this basis, the S-wave velocity structure below each station is inverted using the two-step inversion method and Bootstrap resampling technique and the deep crustal structure of the Xiaojiang fault zone and its adjacent areas is studied. The following conclusions are drawn:=

(1)The crustal S-wave velocity in the study area is obviously non-uniform in both lateral and vertical directions. The overall distribution is as follows: In the near surface, there is a low-velocity layer about 2~4km thick, which may be related to the distribution of shallow sedimentary rocks or Cenozoic soft overburden; The S-wave velocity in the middle and upper crust is alternately distributed with high and low velocity; There is an obvious low-velocity layer in the depth range of 20~35km, mainly intermittently distributed in the Sichuan-Yunnan diamond block west of the Xiaojiang Fault and the Indosinian block south of the Honghe Fault; Besides, there is also local distribution near the Shizong-Mile Fault.

(2)The low-velocity layer in the middle and north segments of the Xiaojiang fault zone are relatively developed, and it is most prominent in the middle segment, with a maximum thickness of about 28km. There is an obvious high-velocity zone in the depth range of 15~25km in the southern segment.

(3)The Poisson’s ratio in the study area is generally low(average 0.24), unevenly distributed, and has drastic lateral changes. The Poisson’s ratio in the Xiaojiang fault zone generally has a segmental feature of higher in the northern segment, the southern segment coming second, and lower in the middle segment. The corresponding relationship between the distribution of low velocity in the crust and Poisson’s ratio in the study area is not obvious, and most of the low velocity layers seem to lack the conditions for partial melting. The differences and inconsistencies in the geophysical results indicate that the deformation evolution mechanism and physical properties of the low velocity layers in the crust are relatively complex.

Key words: Xiaojiang fault zone, P-wave receiver functions, two-step inversion, S-wave velocity, low velocity in the middle-lower crust

摘要：

文中基于2011年9月2日2014年1月16日小江断裂带及邻区48个台站的远震三分量波形数据提取径向P波接收函数, 采用两步反演法和Bootstrap重采样技术反演了各台站下方的S波速度结构, 对小江断裂带及邻区的地壳深部结构进行了研究。结果表明: 1)研究区地壳的S波速度在横向和垂向上都存在明显的非均匀特性, 近地表处有2~4km厚的低速沉积层; 中上地壳的S波速度呈高、低速相间分布; 在20~35km的深度范围内存在明显的低速层, 主要间断分布于小江断裂以西的川滇菱形块体和红河断裂以南的印支块体内部, 另外在师宗-弥勒断裂附近也有局部分布。2)小江断裂带中、北段壳内低速层较为发育, 以中段最为突出, 最厚约达28km; 南段在15~25km深度范围内存在明显的高速区。3)研究区的泊松比普遍较低(平均为0.24), 呈不均匀分布, 且横向变化剧烈, 小江断裂带的泊松比总体呈北段较高、南段次之、中段低的分段特征; 研究区壳内低速分布与泊松比间的对应关系不明显, 大部分低速层似乎缺少发生部分熔融的条件, 其地球物理结果的差异和不一致说明壳内低速层的变形演化机制及物理特性较为复杂。

关键词: 小江断裂带, P波接收函数, 两步反演法, S波速度, 中下地壳低速层

CLC Number:

P315.2

YANG Jian-wen, JIN Ming-pei, CHA Wen-jian, ZHANG Tian-ji, YE Beng. CRUSTAL S-WAVE VELOCITY STRUCTURE BENEATH THE XIAO-JIANG FAULT ZONE AND ADJACENT REGIONS REVEALED BY TWO-STEP INVERSION METHOD OF RECEIVER FUNCTIONS[J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 190-207.

杨建文, 金明培, 茶文剑, 张天继, 叶泵. 利用接收函数两步反演法研究小江断裂带及邻区地壳S波速度结构[J]. 地震地质, 2023, 45(1): 190-207.

Figures/Tables 8

Fig. 1 Stations distribution of ChinArray Phase Ⅰ and Yunnan regional seismic network(a), distribution of stations, faults, vertical profiles in the study area(b).

Fig. 2 Distribution of teleseismic events.

Fig. 3 Waveform fitting and solution uncertainty evaluation of the first-step low-frequency(α=1.0) receiver function inversion for station 53195.

Fig. 4 Waveform fitting and solution uncertainty evaluation of the second-step high-frequency(α=2.5) receiver function inversion for station 53195(Same subgraph description as in Fig. 3).

图b S-wave velocity distribution at the depths of 4km, 10km, 16km, 22km, 30km and 36km in the study areas(Same faults description as in Fig. 1).

Fig. 6 Vertical profile of S-wave velocity near EW and NE-SW direction.

Fig. 7 Vertical profile of S-wave velocity near SN direction.

Fig. 8 Distribution of Poisson’s ratio in the study area(Same faults description as in Fig. 1).

References 36

[1]	何宏林, 池田安隆, 宋方敏, 等. 2002. 小江断裂带第四纪晚期左旋走滑速率及其构造意义[J]. 地震地质, 24(1): 1426.
	HE Hong-lin, Yasutaka Ikeda, SONG Fang-min, et al. 2002. Late Quaternary slip rate of the Xiaojiang Fault and its implication[J]. Seismology and Geology, 24(1): 1426. (in Chinese)
[2]	皇甫岗, 陈颙, 秦嘉政, 等. 2010. 云南地震活动性[M]. 昆明: 云南科技出版社:24.
	HUANGFU Gang, CHEN Yong, QIN Jia-zheng, et al. 2010. The Seismicity in Yunnan[M]. Yunnan Science and Technology Press, Kunming: 24. (in Chinese)
[3]	李海艳, 蔡辉腾, 金星, 等. 2021. 利用远震P波接收函数研究中国福建地区地壳厚度和泊松比[J]. 地球物理学报, 64(3): 805822.
	LI Hai-yan, CAI Hui-teng, JIN Xing, et al. 2021. Analysis of the crustal thickness and Poisson’s ratio in Fujian, southeast China, from teleseismic P-wave receiver functions[J]. Chinese Journal of Geophysics, 64(3): 805822. (in Chinese)
[4]	李建有, 石宝文, 徐晓雅, 等. 2018. 利用远震接收函数探测四川盆地及周边地区的地壳结构[J]. 地球物理学报, 61(7): 27192735.
	LI Jian-you, SHI Bao-wen, XU Xiao-ya, et al. 2018. Crustal structure beneath the Sichuan Basin and adjacent regions revealed by teleseismic receiver functions[J]. Chinese Journal of Geophysics, 61(7): 27192735. (in Chinese)
[5]	李西, 冉勇康, 吴富峣, 等. 2018. 小江断裂带西支晚第四纪强震破裂特征[J]. 地震地质, 40(6): 11791203. doi: 10.3969/j.issn.0253-4967.2018.06.001. DOI
	LI Xi, RAN Yong-kang, WU Fu-yao, et al. 2018. Rupture characteristics of late Quaternary strong earthquakes on the western branch of the Xiaojiang fault zone[J]. Seismology and Geology, 40(6): 11791203. (in Chinese)
[6]	黎源, 雷建设. 2012. 青藏高原东缘上地慢顶部Pn波速度结构及各向异性研究[J]. 地球物理学报, 55(11): 36153624.
	LI Yuan, LEI Jian-she. 2012. Velocity and anisotropy structure of the uppermost mantle under the eastern Tibetan plateau inferred from Pn tomography[J]. Chinese Journal of Geophysics, 55(11): 36153624. (in Chinese)
[7]	刘伟, 吴庆举, 张风雪. 2019. 利用双差层析成像方法反演青藏高原东南缘地壳速度结构[J]. 地震学报, 41(2): 155168.
	LIU Wei, WU Qing-ju, ZHANG Feng-xue. 2019. Crustal structure of southeastern Tibetan plateau inferred from double-difference tomography[J]. Acta Seismologica Sinica, 41(2): 155168. (in Chinese)
[8]	毛燕, 刘自凤, 叶建庆, 等. 2016. 小江断裂带强震危险性分析[J]. 地震研究, 39(2): 213217.
	MAO Yan, LIU Zi-feng, YE Jian-qing, et al. 2016. Analysis on strong earthquake risk of Xiaojiang fault zone[J]. Journal of Seismological Research, 39(2): 213217. (in Chinese)
[9]	钱晓东, 秦嘉政. 2008. 小江断裂带及周边地区强震危险性分析[J]. 地震研究, 31(4): 354361.
	QIAN Xiao-dong, QIN Jia-zheng. 2008. Strong earthquake risk analysis of Xiaojiang fault zone and surrounding areas[J]. Journal of Seismological Research, 31(4): 354361. (in Chinese)
[10]	沈军, 汪一鹏, 宋方敏, 等. 1998. 相对蠕滑速率与特征地震复发间隔的估计: 以小江断裂带为例[J]. 地震地质, 20(4): 328331.
	SHEN Jun, WANG Yi-peng, SONG Fang-min, et al. 1998. Relative creep rate and characteristic earthquake recurrence interval: Example from the Xiaojiang fault zone in Yunnan, China[J]. Seismology and Geology, 20(4): 328331. (in Chinese)
[11]	宋方敏, 汪一鹏, 俞维贤, 等. 1998. 小江活动断裂带[M]. 北京: 地震出版社:1516.
	SONG Fang-min, WANG Yi-peng, YU Wei-xian, et al. 1998. The Xiaojiang Active Fault Zone[M]. Seismological Press, Beijing: 1516. (in Chinese)
[12]	唐彦东, 刘春平, 廖欣, 等. 2013. 小江断裂带中段和南段井水位变化与形变分析[J]. 地震地质, 35(3): 553564. doi: 10.3969/j.issn.0253-4967.2013.03.009. DOI
	TANG Yan-dong, LIU Chun-ping, LIAO Xin, et al. 2013. Analysis of water level changes and deformation process of the middle and southern segments of Xiaojiang fault zone[J]. Seismology and Geology, 35(3): 553564. (in Chinese)
[13]	王椿镛, 楼海, 姚志祥, 等. 2010. 龙门山及其邻区的地壳厚度和泊松比[J]. 第四纪研究, 30(4): 652661.
	WANG Chun-yong, LOU Hai, YAO Zhi-xiang, et al. 2010. Crustal thicknesses and Poisson’s ratios in Longmenshan Mountains and adjacent regions[J]. Quaternary Sciences, 30(4): 652661. (in Chinese)
[14]	王云, 赵慈平, 刘峰, 等. 2014. 小江断裂带及邻近地区温泉地球化学特征与地震活动关系研究[J]. 地震研究, 37(2): 228243.
	WANG Yun, ZHAO Ci-ping, LIU Feng, et al. 2014. Research on relationship between geochemical characteristics of thermal springs and seismic activity in Xiaojiang fault zone and its adjacent area[J]. Journal of Seismological Research, 37(2): 228243. (in Chinese)
[15]	魏文薪. 2012. 川滇块体东边界主要断裂带运动特性及动力学机制研究[D]. 北京: 中国地震局地质研究所:5564.
	WEI Wen-xin. 2012. Study on mechanisms and characteristics of major faults in the eastern boundary of the Sichuan-Yunnan block[D]. Institute of Geology, China Earthquake Administration, Beijing: 5564. (in Chinese)
[16]	杨晶琼, 李月芯, 运乃丹, 等. 2021. 云南小江断裂带北段动态触发现象研究[J]. 地球物理学报, 64(9): 32073219.
	YANG Jing-qiong, LI Yue-xin, YUN Nai-dan, et al. 2021. Dynamic earthquake triggering in the north of Xiaojiang fault zone, Yunnan[J]. Chinese Journal of Geophysics, 64(9): 32073219. (in Chinese)
[17]	易桂喜, 闻学泽, 苏有锦. 2008. 川滇活动地块东边界强震危险性研究[J]. 地球物理学报, 51(6): 17191725.
	YI Gui-xi, WEN Xue-ze, SU You-jin. 2008. Study on the potential strong-earthquake risk for the eastern boundary of the Sichuan-Yunnan active faulted-block, China[J]. Chinese Journal of Geophysics, 51(6): 17191725. (in Chinese)
[18]	张培震, 王敏, 甘卫军, 等. 2003. GPS观测的活动断裂滑动速率及其对现今大陆动力作用的制约[J]. 地学前缘, 10(S1): 8192.
	ZHANG Pei-zhen, WANG Min, GAN Wei-jun, et al. 2003. Slip rates along major active faults from GPS measurements and constraints on contemporary continental tectonics[J]. Earth Science Frontiers, 10(S1): 8192. (in Chinese)
[19]	张培震, 王琪, 马宗晋. 2002. 青藏高原现今构造变形特征与GPS速度场[J]. 地学前缘, 9(2): 442450.
	ZHANG Pei-zhen, WANG Qi, MA Zong-jin. 2002. GPS velocity field and active crustal deformation in and around the Qinghai-Tibet Plateau[J]. Earth Science Frontiers, 9(2): 442450. (in Chinese)
[20]	张天继, 金明培. 2021. 利用远震P波接收函数研究漾濞 M_S6.4 地震孕震环境[J]. 地球物理学报, 64(12): 44624474.
	ZHANG Tian-ji, JIN Ming-pei. 2021. The study of seismogenic environment in Yangbi M_S6.4 earthquake region by teleseismic P-wave receiver function[J]. Chinese Journal of Geophysics, 64(12): 44624474. (in Chinese)
[21]	郑晨, 丁志峰, 宋晓东. 2016. 利用面波频散与接收函数联合反演青藏高原东南缘地壳上地幔速度结构[J]. 地球物理学报, 59(9): 32233236.
	ZHENG Chen, DING Zhi-feng, SONG Xiao-dong. 2016. Joint inversion of surface wave dispersion and receiver functions for crustal and uppermost mantle structure in southeast Tibetan plateau[J]. Chinese Journal of Geophysics, 59(9): 32233236. (in Chinese)
[22]	朱介寿, 王绪本, 杨宜海, 等. 2017. 青藏高原东缘的地壳流及动力过程[J]. 地球物理学报, 60(6): 20382057.
	ZHU Jie-shou, WANG Xu-ben, YANG Yi-hai, et al. 2017. The crustal flow beneath the eastern margin of the Tibetan plateau and its process of dynamics[J]. Chinese Journal of Geophysics, 60(6): 20382057. (in Chinese)
[23]	Ammon C J, Randall G E, Zandt G. 1990. On the nonuniqueness of receiver function inversions[J]. Journal of Geophysical Research: Solid Earth, 95(B10): 1530315318.
[24]	Bai D H, Unsworth M J, Meju M A, et al. 2010. Crustal deformation of the eastern Tibetan plateau revealed by magnetotelluric imaging[J]. Nature Geoscience, 3(5): 358362. DOI
[25]	Bao X W, Sun X X, Xu M J, et al. 2015. Two crustal low-velocity channels beneath SE Tibet revealed by joint inversion of Rayleigh wave dispersion and receiver functions[J]. Earth and Planetary Science Letters, 415:1624. DOI URL
[26]	Berteussen K A. 1977. Moho depth determinations based on spectral-ratio analysis of NORSAR long-period P waves[J]. Physics of the Earth and Planetary Interiors, 15(1): 1327. DOI URL
[27]	Efron B. 1979. Bootstrap methods: Another look at the jackknife[J]. The Annals of Statistics, 7(1): 126.
[28]	Lei J S, Li Y, Xie F R, et al. 2014. Pn anisotropic tomography and dynamics under eastern Tibetan plateau[J]. Journal of Geophysical Research: Solid Earth, 119(3): 21742198.
[29]	Ligorría J P, Ammon C J. 1999. Iterative deconvolution and receiver-function estimation[J]. Bulletin of the Seismological Society of America, 89(5): 13951400. DOI URL
[30]	Liu Q Y, Van D, Li Y, et al. 2014. Eastward expansion of the Tibetan plateau by crustal flow and strain partitioning across faults[J]. Nature Geoscience, 7(5): 361365. DOI
[31]	Peng H C, Yang H Y, Hu J F, et al. 2017. Three-dimensional S-velocity structure of the crust in the southeast margin of the Tibetan plateau and geodynamic implications[J]. Journal of Asian Earth Sciences, 148: 210222. DOI URL
[32]	Shen J, Wang Y P, Song F M. 2003. Characteristics of the active Xiaojiang fault zone in Yunnan, China: A slip boundary for the southeastward escaping Sichuan-Yunnan block of the Tibetan plateau[J]. Journal of Asian Earth Sciences, 21(10): 10851096. DOI URL
[33]	Sun X X, Bao X W, Xu M J, et al. 2014. Crustal structure beneath SE Tibet from joint analysis of receiver functions and Rayleigh wave dispersion[J]. Geophysical Research Letters, 41(5): 14791484. DOI URL
[34]	Wen X Z. 1998. The uniform-slip method for estimating mean slip-rate of strike-slip fault[J]. Journal of Earthquake Prediction Research, 7: 170182.
[35]	Zandt G, Ammon C J. 1995. Continental crust composition constrained by measurements of crustal Poisson’s ratio[J]. Nature, 374(6518): 152154. DOI
[36]	Zhu L P, Kanamori H. 2000. Moho depth variation in southern California from teleseismic receiver functions[J]. Journal of Geophysical Research: Solid Earth, 105(B2): 29692980.