[1] 刘耀炜, 杨选辉, 刘永铭, 等. 地下流体苏门答腊8.7级地震的响应特征[M]//中国地震局监测预报司. 2004年印度尼西亚苏门答腊8.7级大地震及其对中国大陆地区的影响. 北京: 地震出版社, 2005, 131-285. LIU Yao-wei, YANG Xuan-hui, LIU Yong-ming, et al. Response characteristics of underground fluid to Sumatra MS8.7 earthquake[M]//Monitoring and Forecasting Department of China Seismological Bureau. The 8.7 magnitude earthquake in Sumatra, Indonesia, 2004 and its impact on Chinese mainland. Beijing: Seismological Press, 2005, 131-285 (in Chinese). [2] 王永刚, 孙丽. 2016年青海门源6.4级地震周边地下流体同震响应特征研究[J]. 地震研究, 2016, 39(增刊1): 83-88. WANG Yong-gang, SUN Li. Study on coseismic response characteristic of underground fluid in and around the epicenter of Qinghai Menyuan MS6.4 earthquake in 2016[J]. Journal of Seismological Research, 2016, 39(S1): 83-88 (in Chinese). [3] 汪成民, 车用太, 万迪. 地下水微动态研究[M]. 北京: 地震出版社, 1988. WANG Cheng-min, CHE Yong-tai, WAN Di. Study on micro dynamic of groundwater[M]. Beijing: Seismological Press, 1988 (in Chinese). [4] 张昭栋, 赵淑平, 董传富, 等. 井水位阶变与含水层所受体应力之间的定量关系[J]. 地球物理学报, 1994, 37(增刊1): 222-229. ZHANG Zhao-dong, ZHAO Shu-ping, DONG Chuan-fu, et al. Quantitative relationship between the step variation well water level and the bulk stress in the aquifer[J]. Chinese Journal of Geophysics, 1994, 37(S1): 222-229 (in Chinese). [5] 黄辅琼, 迟恭财, 徐桂明, 等. 大陆地下流体对台湾南投7.6级地震的响应研究[J]. 地震, 2000, 20(增刊1): 119-125. HUANG Fu-qiong, CHI Gong-cai, XU Gui-ming, et al. Research on the response anomalies of subsurface fluid in mainland monitoring network to the Nantou earthquake with MS7.6[J]. Earthquake, 2000, 20(S1): 119-125 (in Chinese). [6] 廖丽霞, 秦双龙, 陈昌泳. 不同采样率水位同震响应能力及其特征分析[J]. 地震地磁观测与研究, 2013, 34(3): 150-155. LIAO Li-xia, QIN Shuang-long, CHEN Chang-yong. Comparison of the ability for recording coseismic response using water level of different sampling ratio[J]. Seismological and Geomagnetic Observation and Research, 2013, 34(3): 150-155 (in Chinese). [7] 万登堡. 井孔水位记震能力变化与近大地震关系研究[J]. 地震研究, 1992, 15(4): 381-391. WAN Deng-bao. Recording capacity variation of water level in wells and its relation to large earthquakes[J]. Journal of Seismological Research, 1992, 15(4) : 381-391 (in Chinese). [8] 鱼金子, 车用太, 王爱英, 等. 大同—阳高地震前静乐井水位记震能力的异常及其意义[J]. 山西地震, 1995, (1): 50-53. YU Jin-zi, CHE Yong-tai, WANG Ai-ying, et al. Anomaly of the ability for recording earthquake of Jingle well water level before the Datong-Yanggao earthquake[J]. Earthquake Research in Shanxi, 1995, (1): 50-53 (in Chinese). [9] 丁仁杰, 黄才中, 毛正毅, 等. 深井水位记震特征研究[J]. 地震学刊, 1988, (4): 35-46. DING Ren-jie, HUANG Cai-zhong, MAO Zheng-yi, et al. Study on seismic recording characteristics of deep well water level[J]. Journal of Seismology, 1988, (4): 35-46 (in Chinese). [10] 丁仁杰, 毛正毅, 郭惠敏, 等. 井孔水位记震能力与地震关系的探讨[M]//国家地震局科技监测司所编. 《地震预报方法实用化研究文集》水位水化专集. 北京: 地震出版社, 1990, 186-192. DING Ren-jie, MAO Zheng-yi, GUO Hui-min, et al. Discussion on the relationship between seismic recording ability of borehole water level and earthquake[M]//Science and technology monitoring department of State Seismological Bureau. Album of Water level and hydration which in a collection of practical research on earthquake prediction methods. Beijing: Seismological Press, 1990, 186-192 (in Chinese). [11] 胡先明. 深井水位记震能力与地震预报[J]. 大地测量与地球动力学, 2007, 27(9): 74-78. HU Xian-ming. Recording earthquake ability of water level of deep well and earthquake prediction[J]. Journal of Geodesy and Geodynamics, 2007, 27(9): 74-78 (in Chinese). [12] 张清秀, 郑小菁, 林木金, 等. 永春井水位对远大地震的记震能力及同震效应特征分析[J]. 华南地震, 2011, 31(3): 33-40. ZHANG Qing-xiu, ZHENG Xiao-jing, LIN Mu-jin, et al. Analysis of the ability of recording teleseismic and characteristics of coseismic effect recorded by the Yongchun well water level[J]. South China Journal of Seismology, 2011, 31(3): 33-40 (in Chinese). [13] 车用太, 鱼金子. 地下水动态映震机制的试验与观测研究[J]. 地震研究, 1992, (2): 171-179. CHE Yong-tai, YU Jin-zi. Test and observational studies of the earthquake-corresponding mechanism of ground water behaviours[J]. Journal of Seismological Research, 1992, (2): 171-179 (in Chinese). [14] 张昭栋, 迟镇乐, 陈会民, 等. 水井含水层导水系数及其对地震波的响应[J]. 内陆地震, 1999, (3): 207-214. ZHANG Zhao-dong, CHI Zhen-le, CHEN Hui-min, et al. The transmissibility coefficient of well aquifer and its response to seismic wave[J]. Inland Earthquake, 1999, (3): 207-214 (in Chinese). [15] 张昭栋, 迟镇乐, 陈会民, 等. 井水位的振荡与地震波[J]. 地震研究, 2000, 23(4): 418-425. ZHANG Zhao-dong, CHI Zhen-le, CHEN Hui-min, et al. Vibration of water level in well and earthquake wave[J]. Journal of Seismological Research, 2000, 23(4): 418-425 (in Chinese). [16] 陈大庆, 刘耀炜, 杨选辉, 等. 远场大震同震水位振荡、 水温下降类型机理初步研究[M]//国家地震局地壳应力研究所. 地壳构造与地壳应力文集. 北京: 地震出版社, 2006:176-187. CHEN Da-qing, LIU Yao-wei, YANG Xuan-hui, et al. On the mechanism of water temperature drop and water level oscillation in response to remote strong earthquakes[M]//Institute of crustal stress, China Seismological Bureau. Bulletin of the Institute of Crustal Dynamics.Beijin:Seismological Press, 2006: 176-187 (in Chinese). [17] 廖丽霞. 福建地下流体典型异常核实及分析应用[M]. 北京: 地震出版社, 2019. LIAO Li-xia. Analysis and application of typical underground fluid abnormal verification in Fujian Province[M]. Beijing: Seismological Press, 2019 (in Chinese). [18] Roeloffs E A. Persistent water level changes in a well near Parkfield California due to local and distant earthquakes[J]. Journal of Geophysical Research, 1998, 103(B1): 869-889. [19] King C Y, Azuma S, Igarashi G, et a1. Earthquake-related water-level changes at 16 closely clustered wells in Tono, central Japan[J]. Journal of Geophysical Research, 1999, 104(B6): 13073-13082. [20] Montgomery D R, Manga M. Streamflow and water well responses to earthquakes[J]. Science, 2003, 300(5628): 2047-2049. [21] Shi Z M, Wang G C, Manga M, et al. Mechanism of co-seismic water level change following four great earthquakes-insights from co-seismic responses throughout the Chinese mainland[J]. Earth and Planetary Science Letters, 2015, 430: 66-74. [22] Wang C Y. Liquefaction beyond the near field[J]. Seismological Research Letters, 2007, 78(5): 512-517. [23] Wang C Y, Manga M. Hydrologic responses to earthquakes and a general metric[J]. Geofluids, 2010, 10(1/2): 210-216. [24] Brodsky E E, Roeloffs E, Woodcock D, et al. A mechanism for sustained groundwater pressure changes induced by distant earthquakes[J]. Journal of Geophysical Research, 2003, 108(B8): 2390. [25] Woodcock D, Roeloffs E. Seismically induced water-level oscillations in a fractured-rock aquifer well near Grants Pass, Oregon[J]. Oregon Geology, 1996, 58: 27-33. [26] Brodsky E E, Prejean S G. New constraints on mechanisms of remotely triggered seismicity at Long Valley Caldera[J]. Journal of Geophysical Research, 2005, 110(B4): 1-14. [27] Hill D P, Prejean S G. Dynamic triggering in treatise of geophysics, elsevier[J]. Amsterdam, 2007, 4: 293-320. [28] Wang C Y, Wong A, Dreger D S, et al. Liquefaction limit during earthquakes and underground explosions: Implications on ground-motion attenuation[J]. Bulletin of the Seismological Society of America, 2006, 96(1): 355-363. [29] 付虹, 刘丽芳, 王世芹, 等. 地方震及近震地下水同震震后效应研究[J]. 地震, 2002, 22(4): 55-66. FU Hong, LIU Li-fang, WANG Shi-qin, et al. Research on coseismic and post seismic effect of ground water for the local and near earthquake[J]. Earthquake, 2002, 22(4): 55-66 (in Chinese). [30] 崔瑾, 丁风和, 曾宪伟, 等. 宁夏井水位观测同震响应特征研究及机理探讨[J]. 地球物理学进展, 2019, 34(4): 1281-1287. CUI Jin, DING Feng-he, ZENG Xian-wei, et al. Study on coseismic response characteristics and mechanism of well water level observation in Ningxia[J]. Progress in Geophysics, 2019, 34(4): 1281-1287 (in Chinese). [31] Sun X L, Xiang Y, Shi Z M, et al. Sensitivity of the response of well-aquifer systems to different periodic loadings: A comparison of two wells in Huize, China[J]. Journal of Hydrology, 2019, 572: 121-130. [32] 鱼金子, 车用太, 王爱英, 等. 水震波异常与中期强震危险性关系初探[J]. 地震, 1993, (4): 30-37. YU Jin-zi, CHE Yong-tai, WANG Ai-ying, et al. Preliminary study on relations between the anomalies of seismic wave of water level and the earthquake risk[J]. Earthquake, 1993, (4): 30-37 (in Chinese). |