图书馆VIP讲席教授,科技部中青年科技领军人才。2003年12月获得美国University of Wisconsin-Madison (UW-Madison)地震学和地球物理学博士学位。2004-2007年在UW-Madison担任助理和副研究员,2007至2012年在麻省理工学院地球和大气行星科学系(EAPS)以及地球资源实验室(Earth. Resources Lab)担任Research Scientist。主要从事地震成像新算法的研发和对不同构造区域不同尺度地下结构进行精细成像研究,及不同资源开采过程中诱发地震监测与成像。发展了广泛应用于全球地震学界的双差地震层析成像算法,实现了对发震构造的“解剖”,为认识中强地震发震机理提供了关键的技术手段,并在地震断层成像等领域取得了一系列具有国际影响力的成果。在诱发地震监测领域,发展了先进的微地震监测与成像系统,并用于煤矿、盐矿、金属矿、页岩气、地热等资源的开发。现已发表国际国内学术期刊论文100余篇,包括在自然-地球科学,自然-通讯,Geology、EPSL、JGR-Solid Earth、GRL、GJI、Geothermics等国际著名期刊发表的第一和通信作者论文70余篇, 论文Google学术引用7500多次,其中1篇论文为国际SCI高被引论文,2021和2022年入选Elsevier地球物理领域中国高被引学者。其科研成果分别在2004年被Geology杂志,2018年被AGU的EOS网站作为研究热点报道,并且在2019,2020和2021年被国家自然科学基金委网站报道。承担了国家重点研发计划“多尺度壳幔流变结构及其对地震和火山活动的作用机
制”项目(负责人),“不同构造类型活动断裂三维建模关键技术及应用”项目第二课题(课题负责人),国家重大油气专项“储层改造关键技术与装备”子课题,国家自然科学基金委重点基金,重点联合基金等十多项科研项目。2010-2013期间曾担任美国地震学会学报(BSSA)的副主编(AE),2016-2021期间分别担任国际核心地学期刊JGR-Solid Earth和GSA-Bulletin的副主编。目前担任EarthquakeScience,地震地质,地震学报等期刊的副主编和编委,中国地震学会地震学专业委员会副主任委员,中国地球物理学会浅地表专委会副主任委员,以及多个学会委员。
(1)国家重点研发计划, 多尺度壳幔流变结构及其对地震和火山活动的作用机制,2022/12至 2027/11, 2000万元, 在研, 主持 (2022YFF0800700)
(2)国家自然科学基金委员会, 重点项目, 利用地震和重力联合反演构建中国区域岩石圈参考速度模型, 2023-01-01 至 2027-12-31, 269万元, 在研, 主持 (42230101)
(3)国家重点研发计划,“不同构造类型活动断裂三维建模关键技术及应用”课题三“活动断裂地下结构三维成像关键技术”,2018-2021
(4)国家基金委重点联合基金项目,”地震、重力与大地电磁联合反演算法研究及在川滇地区岩石圈结构高分辨率成像的应用”,2019-2022
(5)国家基金委国际(地区)合作与交流项目,“基于全波形的主动源和被动源地震多尺度地下介质成像和监测研究”,2019-2022
(6)国家基金委国际(地区)合作与交流项目,“基于先进地震成像和大地测量反演算法确定智利地区高分辨地壳结构及其变形特征“,2018-2022
(7)国家重点研发计划,“三江地区深地震反射/折射剖面全波形速度成像(“青藏高原碰撞造山成矿系统深部结构与成矿过程”专题),2016-2020
(8)国家科技重大专项,“微地震多井联合监测矩张量反演技术研究”(“大型油气田及煤层气”项目专题),2016-2020,
(9)地质调查项目委托业务,“干热岩试采压裂诱发地震研究”, 2019/07-2019/12
(10)国家自然科学基金面上项目“页岩气开发过程中人工水压裂诱发的微地震井下监测方法研究”
(11)国家自然科学基金面上项目“综合地震成像方法研究芦山地震震源区及其周边精细结构“
发表文章
2023
152. GAO, J., ZHANG*, H., ZHA, H., WU, J., WU, D., XU, Y., PAN, D. and GU, N., The effect of different arrays and noise source distribution on microtremor imaging and its application in solute salt mine cavity detection. Chinese Journal of Geophysics, 66 (6), 2489-2506
151. Liu, Yunlong, Vera Schlindwein, Lei Qiu, Minghui Zhao, Haijiang Zhang, Jianping Zhou, Jiazheng Zhang, Hanchuang Wang, Tao Wu, and Xianming Deng. Seismic observation of an active detachment faulting system beneath the Longqi hydrothermal field at the ultraslow spreading southwest Indian ridge. Deep Sea Research Part I: Oceanographic Research Papers (2023): 104072.
150. Hao, Aowei, Haijiang Zhang*, Shoucheng Han, and Wenliang Xu. High-resolution Moho depth and Vp/Vs ratio distributions in northeast China from joint inversion of receiver functions and gravity data and their geological implications. Science China Earth Sciences (2023): 1-14.
149. Anyiam, Uzonna Okenna, Haijiang Zhang*, Yuyang Tan, Jiawei Qian, Lei Gao, Ying Liu, Kezhen Zuo, and Cuiping Zhao. Enhanced 3D velocity structure, seismicity relocation and basement characterization of Changning shale gas and salt mining regions in southern Sichuan basin. Frontiers in Earth Science 10 (2023): 1082122.
148. Miao, S., Cheng, G., Zhang*, H., Huang, Y., Gu, N., Zha, H. and Gao, J., 2022. Efficiently identifying coalbed methane enrichment areas by detecting and locating low-frequency signals in the coal mine. Geohazard Mechanics, 1(1), pp.86-93.
147. Hou*, Z., Wang*, Q., Zhang*, H., Xu, B., Yu, N., Wang, R., Groves, D.I., Zheng, Y., Han, S., Gao, L. and Yang, L., 2023. Lithosphere architecture characterized by crust–mantle decoupling controls the formation of orogenic gold deposits. National Science Review, 10(3), p.nwac257.
146. Hou*, Zeng-Qian, Rui Wang*, Haijiang Zhang* et al., (2023), Formation of giant copper deposits in Tibet driven by tearing of the subducted Indian plate, Earth-Science Reviews, 243(1):104482
145. Zhang*, H., Lü, QT., Wang, XL. et al. Seismically imaged lithospheric delamination and its controls on the Mesozoic Magmatic Province in South China. Nature Communications 14, 2718 (2023). https://doi.org/10.1038/s41467-023-37855-5
144. Yuyang Tan, Jiawei Qian, Jun Hu*, Haijiang Zhang*, Huilin Xing, Junlun Li, Jian Xu, Wen Yang, Ning Gu, Siyu Miao, Tomographic evidences for hydraulic fracturing induced seismicity in the Changning shale gas field, southern Sichuan Basin, China, Earth and Planetary Science Letters, Volume 605, 2023, 118021, https://doi.org/10.1016/j.epsl.2023.118021.
143. Li*, J., Xu, J., Zhang*, H. et al. High seismic velocity structures control moderate to strong induced earthquake behaviors by shale gas development. Commun Earth Environ 4, 188 (2023). https://doi.org/10.1038/s43247-023-00854-x
2022
142. Bao, H., Xu, L., Meng, L., Ampuero, J.P., Gao, L. and Zhang, H., 2022. Global frequency of oceanic and continental supershear earthquakes. Nature Geoscience, 15(11), pp.942-949.
141. 查华胜,张海江*,连会青等(2022). 潘二煤矿A组煤层底板灰岩水害微震监测, 煤炭学报,47(8), 3001-3014.
140. 陈国艺, 杨文, 谭玉阳 , 张海江 , 李俊伦*, 基于机器学习和台阵相关性的水力压裂微地震事件自动识别及到时拾取 , 地球物理学报 , 66 (4), 1558-1574
139. Han, S., H. Zhang*, L. Gao, Y. Liu, C. Chai, and M. Maceira (2022). Joint inversion of body wave arrival times, surface wave dispersion data and receiver functions: Method and Application to south China, Journal of Geophysical Research: Solid Earth, 127(9), e2022JB024083, DOI: 10.1029/2022JB024083.
138. 郝奥伟, 张海江*, 韩守诚, 高磊. 2022. 基于多台站的接收函数和重力联合反演确定莫霍面起伏和地壳平均波速比. 地震学报[J], 44(0): 1-16. DOI: 10.11939/jass.20210179
137. Qian J, Wang K, Zhang* H, Tan Y, Xu C, Wang Q, Xiong Q and Malinowski M (2022), First observation of paired microseismic signals during solution salt mining. Front. Earth Sci. 10:952314. doi: 10.3389/feart.2022.952314
136. Tan, Y., Xing, H., Jin, Z., Wang, J., Pang, S., Guo, H., Zhang, H. and Gao, L. (2022). Seismogenesis of the 2021 Mw 7.1 earthquake sequence near the northeastern Japan revealed by double-difference seismic tomography. Earth and Planetary Science Letters, 594, p.117738.
135. Hu, Y., Li, J., & Zhang, H. (2022). Waveform Energy Focusing Tomography With Passive Seismic Sources. Frontiers in Earth Science, 10, 900435.
134. Wang, K., Qian, J., Zhang*, H., Gao, J., Bi, D., & Gu, N. (2022). Seismic imaging of mine tunnels by ambient noise along linear arrays. Journal of Applied Geophysics, 104718.
133. Navarro-Aránguiz, A., Comte, D., Farías, M., Roecker, S., Calle-Gardella, D., Zhang, H., ... & Rietbrock, A. (2022). Subduction erosion and basal accretion in the Central Chile subduction wedge inferred from local earthquake tomography. Journal of South American Earth Sciences, 115, 103765.
132. 杨少博,王炳文,高级*,张海江 (2022), 东祁连山北缘断裂带基于深度学习的密集台阵地震事件快速检测与定位研究, 震灾防御技术, 17 (1), 38−45
131. Yang, S., Zhang*, H., Gu, N., Gao, J., Xu, J., Jin, J., ... & Yao, H. (2022). Automatically Extracting Surface‐Wave Group and Phase Velocity Dispersion Curves from Dispersion Spectrograms Using a Convolutional Neural Network. Seismological Research Letters, 93(3), 1549-1563.
130. Gu, N., Gao, J., Wang, B., Lu, R., Liu, B., Xu, X., & Zhang*, H. (2022). Ambient noise tomography of local shallow structure of the southern segment of Tanlu fault zone at Suqian, eastern China. Tectonophysics, 825, 229234.
129. Lei Gao, Haijiang Zhang*, Lina Gao, Chuansong He, Hailiang Xin, Weisen Shen (2022),High-resolution Vs tomography of South China by joint inversion of body wave and surface wave data,Tectonophysics, 824, 229228.
128. Han, S., Zhang*, H., Xin, H., Shen, W. and Yao, H., 2022. USTClitho2. 0: Updated Unified Seismic Tomography Models for Continental China Lithosphere from Joint Inversion of Body‐Wave Arrival Times and Surface‐Wave Dispersion Data. Seismological Research Letters, 93(1), pp.201-215. (模型下载:https://github.com/ShouchengHan/USTClitho2.0)
2021
127. HUANG, Y., ZHA, H., GAO, J., LINGHU, J., XUAN, J., ZHOU, J., DONG, R., HUO, J. and ZHANG, H., 2021. Predicting the distribution of coalbed methane by ambient noise tomography with a dense seismic array. Chinese Journal of Geophysics, 64(11), pp.3997-4011.
126. Ning GU, Michal Chamarczuk, Ji GAO, Michal Malinowski, Haijiang ZHANG, 2021, Passive Seismic Structure Imaging of a Coal Mine by Ambient Noise Seismic Interferometry on a Dense Array, Acta Geologica Sinica‐English, 95, S1, 37-39
125. Ning Gu, Haijiang Zhang*, Nori Nakata, Ji Gao, 2021, Fault detection by reflected surface waves based on ambient noise interferometry, Earthquake Research Advances, Volume 1, Issue 4, 100035, ISSN 2772-4670, https://doi.org/10.1016/j.eqrea.2021.100035.
124. Miao, S., Zhang*, H., Tan, Y. and Lin, Y., 2021. Development of a new high resolution waveform migration location method and its applications to induced seismicity. Earth and Planetary Physics, 5(6), pp.532-546.
123. Lu, P., Zhang*, H., L., Gao. and Comte, D., 2020, December. Seismic Imaging of the Double Seismic Zone in the subducting slab in Northern Chile. Earthquake Research Advances, Volume 1, Issue 1, 100003, ISSN 2772-4670, https://doi.org/10.1016/j.eqrea.2021.100003.
122. Liu, Y., Zhang*, H., Kendall, J.M. and Wookey, J., 2021. Conjugate fault deformation revealed by aftershocks of the 2013 Mw6. 6 Lushan earthquake and seismic anisotropy tomography. Geophysical Research Letters, 48(14), p.e2021GL092563.
121. Wei, S.S., Ruprecht, P., Gable, S.L., Huggins, E.G., Ruppert, N., Gao, L. and Zhang, H., 2021. Along-strike variations in intermediate-depth seismicity and arc magmatism along the Alaska Peninsula. Earth and Planetary Science Letters, 563, p.116878.
120. Guo, H., McGuire, J.J. and Zhang*, H., 2021. Correlation of porosity variations and rheological transitions on the southern Cascadia megathrust. Nature Geoscience, 14(5), pp.341-348.
119. Liu Y, Yao H, Zhang H, Fang H. The Community Velocity Model V. 1.0 of Southwest China, Constructed from Joint Body‐and Surface‐Wave Travel‐Time Tomography. Seismological Research Letters. 2021
118. Yang, W., Chen, G., Meng, L., Zang, Y., Zhang, H. and Li, J., 2021. Determination of the local magnitudes of small earthquakes using a dense seismic array in the Changning? Zhaotong Shale Gas Field, Southern Sichuan Basin. Earth and Planetary Physics, 5(3), pp.1-15.
117. Chai C, Delorey AA, Maceira M, Levandowski W, Guyer RA, Zhang H, Coblentz D, Johnson PA. A 3D Full Stress Tensor Model for Oklahoma. Journal of Geophysical Research (Solid Earth). 2021 Apr;126(4):e21113.
116. Yang, S., Hu, J., Zhang,* H. and Liu, G., 2021. Simultaneous earthquake detection on multiple stations via a convolutional neural network. Seismological Research Letters, 92(1), pp.246-260
2020
115. 丁成, 李俊伦*, 王晓山, 谭玉阳 and 张海江, 2020. 首都圈地区中小地震全波形震源机制反演. 地震, 40(4), pp.1-22.
114. Li, H., Li, J., Gu, N., Gao, J. and Zhang, H., 2020. Ambient Noise Surface Wave Reverse Time Migration for Fault Imaging. Journal of Geophysical Research: Solid Earth, 125(12), p.e2020JB020381.
113. Zuo, K., Zhao, C. and Zhang, H., 2020. 3D Crustal Structure and Seismicity Characteristics of Changning–Xingwen Area in the Southwestern Sichuan Basin, China. Bulletin of the Seismological Society of America, 110(5), pp. 2154-2167
112. Tan, Yuyang, Haijiang Zhang*, Junlun Li, Chen Yin and Furong Wu (2020), Full moment tensor inversion constrained by double-couple focal mechanism for induced seismicity, Earthquake Science, accepted.
111. Chang, Kai, Haijiang Zhang* (2020), Passive seismic imaging of near vertical structures around the SAFOD site, California, jointly using scattered P and SH waves, JGR-Solid Earth, in revision.
110. Ji Gao, Haijiang Zhang*, Huiping Zhang, Senqi Zhang, Zhengpu Cheng (2020), Three-dimensional magnetotelluric imaging of the SE Gonghe Basin: implication for the orogenic uplift in the northeastern margin of the Tibetan plateau, Tectonophysics, 228525.
109. Chen, Yukuan, Haijiang Zhang*, David W. Eaton (2020), Real-time earthquake location based on the Kalman filter formulation. Geophysical Research Letters, 46, e2019GL086240. https://doi.org/10.1029/2019GL086240.
108. Gao, Ji, Haijiang Zhang*, Senqi Zhang et al., 2020, Magma recharging beneath the Weishan volcano of the intraplate Wudalianchi volcanic field, northeast China, implied from 3-D magnetotelluric imaging: Geology, v. 48, p. XXX–XXX, https://doi.org/10.1130/G47531.1
107. Ye Lin, Haijiang Zhang*, Yukuan Chen, Junlun Li (2020). Source-Independent Passive Seismic Reverse-time Structure Imaging with Grouping Imaging Condition: Method and Application to Microseismic Events Induced by Hydraulic Fracturing, Journal of Geophysical Research-Solid Earth, in press, doi:10.1029/2019JB018043
106. Jing Hu, Hongrui Qiu, Haijiang Zhang*, Yehuda Ben-Zion (2020), Using deep learning to derive shear wave velocity models from surface wave dispersion, Seismological Research Letters, 91 (3): 1738–1751. https://doi.org/10.1785/0220190222
105. Yuyang Tan, Jun Hu*, Haijiang Zhang*, Yukuan Chen, Jiawei Qian, Quanfeng Wang, Huasheng Zha, Pan Tang, Zhou Nie (2020), Hydraulic Fracturing Induced Seismicity in the Southern Sichuan Basin Due to Fluid Diffusion Inferred from Seismic and Injection Data Analysis, Geophysical Research Letters, e2019GL084885. https://doi.org/10.1029/2019GL084885
104. L Linkimer, S Beck, G Zandt, P Alvarado, M Anderson, H Gilbert, H Zhang (2020), Lithospheric structure of the Pampean flat slab region from double-difference tomography, Journal of South American Earth Sciences 97, 102417.
2019
103. 谭玉阳,胡隽,张海江等 (2019).利用全波形匹配方法确定水力压裂诱发地震震源机制.地球物理学报,62(11): 4417-4436. doi: 10.6038/cjg2019M0516
102. Ben-Zion, Yehuda, Xiaofei Chen, and Haijiang Zhang (2019), Frontiers in Studies of Earthquakes and Faults: Introduction, Pure and Applied Geophysics, 176, Issue 3, pp 979–982, doi: 10.1007/s00024-019-02139-x
101. Zhang, Haijiang*, Fan Wang, Robert Myhill*, and Hao Guo (2019), Slab morphology and deformation beneath Izu-Bonin, Nature Communications, 10, Article number: 1310, https://www.nature.com/articles/s41467-019-09279-7
100. Jing Hu, Haijiang Zhang*, Haiying Yu (2019), Accurate determination of P-wave back azimuth and slowness parameters by sparsity constrained seismic array analysis, Geophysical Journal International, 216, 1-18, doi: 10.1093/gji/ggy390
99. Gu, Ning, Kangdong Wang, Ji Gao, Ning Ding, Huajian Yao, Haijiang Zhang* (2019), Shallow crustal structure of the Tanlu fault zone near Chao Lake in eastern China by direct surface wave tomography from local dense array ambient noise analysis, Pure and Applied Geophysics, Volume 176, Issue 3, pp 1193–1206
98. Fang, Hongjian, Huajian Yao, Haijiang Zhang, Clifford Thurber, Yehuda Ben-Zion, Robert D. van der Hilst (2019), Vp/Vs tomography in the southern California plate boundary region using body- and surface-wave traveltime data, Geophysical Journal International, 216, 609–620, doi: 10.1093/gji/ggy458
97. Share, Pieter-Ewald, Hao Guo, Clifford Thurber, Haijiang Zhang, Yehuda Ben-Zion (2019), Seismic imaging of the Southern California plate boundary around the South-Central Transverse Ranges using double-difference tomography, Pure and Applied Geophysics, 176 (3), 1117–1143
96. 缪思钰,张海江, 陈余宽,谭玉阳,苗园园,黄振华,王飞,谢庆明(2019),基于微地震定位和速度成像的页岩气水力压裂地面微震监测,石油物探,58(2).262-271
95. 张雪敏, 付丽华*, 张海江, 彭佳明(2019), 基于正交秩-1矩阵追踪的天然地震数据重建研究:以加州San Jacinto断层密集地震台阵为例, 地球物理学报, 62(4), 1427-1439。
94. Hailiang Xin, Haijiang Zhang*, Min Kang, Rizheng He, Lei Gao, Ji Gao (2019), High-resolution lithospheric velocity structure of continental China by double-difference seismic travel time tomography, Seismological Research Letters, 90 (1): 229-241, doi:10.1785/0220180209. (PDF下载,USTClitho1.0模型)https://pubs.geoscienceworld.org/ssa/srl/article/566123/high-resolution-lithospheric-velocity-structure-of
2018
93. Qian, Jiawei, Haijiang Zhang*, Erik Westman (2018), New time-lapse seismic tomographic scheme based on double-difference tomography and its application in monitoring temporal velocity variations caused by underground coal mining, Geophysical Journal International, 215, 2093–2104, doi: 10.1093/gji/ggy404
92. Fang, H, H. Yao and H. Zhang (2018), Earthquake rupture imaging with teleseismic array data in the wavelet domain: methodology and application to the 2011 Tohoku earthquake, Geophysical Journal International, https://doi.org/10.1093/gji/ggy384
91. Liu, Ying, Haijiang Zhang*, Hongjian Fang, Huajian Yao, Ji Gao (2018), Ambient noise tomography of three-dimensional near-surface shear-wave velocity structure around the hydraulic fracturing site using surface microseismic monitoring array, Journal of Applied Geophysics, 159, 209–217. https://doi.org/10.1016/j.jappgeo.2018.08.009
90. Hao Guo, Haijiang Zhang*, Berenice Froment (2018), Berenice Froment, Structural control on earthquake behaviors revealed by high-resolution Vp/Vs imaging along the Gofar transform fault, East Pacific Rise, Earth and Planetary Science Letters, 499, 243–255, https://doi.org/10.1016/j.epsl.2018.07.037
89. Ji Gao, Haijiang Zhang*, Senqi Zhang, Xiaobin Chen et al. (2018), Three-dimensional Magnetotelluric Imaging of the Geothermal System beneath the Gonghe Basin, Northeast Tibetan Plateau, Geothermics, 76, 15-25, doi: 10.1016/j.geothermics.2018.06.009 (https://authors.elsevier.com/a/1XH~s1LQRpi-PL)
88. Yunlong Liu, Chunhui Tao*, Cai Liu, Lei Qiu, Vera Schlindwein, Haijiang Zhang, You Tian & Hanchuang Wang (2018) Seismic activity recorded by a single OBS/H near the active Longqi hydrothermal vent at the ultraslow spreading Southwest Indian Ridge (49°39′ E), Marine Georesources & Geotechnology, DOI: 10.1080/1064119X.2017.1420114
87. Golos, E. M.* , H. Fang, H. Yao, H. Zhang, S. Burdick, F. Vernon, A. Schaeffer, S. Lebedev and R. D. van der Hilst (2018), Shear-wave tomography beneath the United States using a joint inversion of surface and body waves, Journal of Geophysical Research-Solid Earth, 123 (6), 5169-5189, doi: 10.1029/2017JB014894
86. Yuyang Tan, Haijiang Zhang*, Junlun Li, Chen Yin, and Furong Wu (2018), Focal mechanism determination for induced seismicity using the neighborhood algorithm, Geophysical Journal International, 214(3), 1715-1731.
85. Liu, Hao, Fei Chen, Wei Leng*, Haijiang Zhang*, Yigang Xu (2018), Crustal footprint of the Hainan plume beneath southeast China, Journal of Geophysical Research-Solid Earth, 123(4), 3065-3079, doi:10.1002/2017JB014712 (Research spotlight: https://eos.org/research-spotlights/linking-mantle-plumes-to-volcanoes-and-hot-spot-tracks)
84. Andri D. Nugraha, Hasbi A. Shiddiqi, Sri Widiyantoro, Clifford H. Thurber, Jeremy D. Pesicek, Haijiang Zhang, Samsul H. Wiyono, Mohamad Ramdhan, Wandono, and Mahsyur Irsyam (2018), Hypocenter Relocation along the Sunda Arc in Indonesia, Using a 3D Seismic-Velocity Model, Seismological Research Letters, 89 (2A): 603-612, doi: 10.1785/0220170107.
83. Chenyu Li*, Zhigang Peng, Dongdong Yao, Hao Guo, Zhongwen Zhan, Haijiang Zhang (2018), Abundant Aftershock Sequence of the 2015 Mw7.5 Hindu Kush Intermediate-Depth Earthquake, Geophysical Journal International, 213 (2), 1121–1134, doi: 10.1093/gji/ggy016.
82. Gao J., and H. Zhang*(2018), An efficient sequential strategy for realizing cross-gradient joint inversion: method and its application to two dimensional cross borehole seismic travel time and DC resistivity tomography, Geophysical Journal International, 213(2), 1044–1055, doi:10.1093/gji/ggy026 (PDF下载)
81. Lin, Ye, Haijiang Zhang*, Xiaofeng Jia (2018), Target-oriented imaging of hydraulic fractures by applying the staining algorithm for downhole microseismic migration, Journal of Applied Geophysics, 150, 278–283.
2017
80. 危自根, 储日升, 李志伟 , 盛敏汉 ,张海江,王宝善(2017),利用近震高频接收函数研究四川理县西山村滑坡体结构,地球物理学报,60,3793-3803
79. 于辉,张海江(2017),水力压裂微地震监测稳定共振频率信号的解释,物探化探计算技术,39(171),90-95
78. Syracuse E. M.* , H. Zhang*, M. Maceira (2017), Joint inversion of seismic and gravity data for imaging seismic velocity structure of the crust and upper mantle beneath Utah, United States, Tectonophysics, 718,105-117,doi:10.1016/j.tecto.2017.07.005
77. Guo, Hao, H. Zhang*, R.M. Nadeau, and Z. Peng (2017), High-resolution deep tectonic tremor locations beneath the San Andreas fault near Cholame, California, using the double-pair double-difference location method, Journal of Geophysical Research-Solid Earth, 122,3062-3075, doi: 10.1002/2016JB013919. http://onlinelibrary.wiley.com/doi/10.1002/2016JB013919/full
76. Yin J., Yao H.*, Yang H,, Liu J., Qin W., Zhang H. (2017). Frequency-dependent rupture process, stress change, and seismogenic mechanism of the 25 April 2015 Nepal Gorkha Mw 7.8 earthquake. Science China Earth Sciences, 60, 796-808
75. Gao, L., H. Zhang*, H. Yao and H. Huang (2017), 3D Vp and Vs models of southeastern margin of the Tibetan plateau from joint inversion of body-wave arrival times and surface-wave dispersion data, Earthquake Science, 30,17-32,doi:10.1007/s11589-017-0175-6
74. 高级,张海江*(2017), 基于共轭梯度的全通道3D井地井电阻率成像研究, 地球物理学进展,32(1):0135-0141, doi: 10.6038/pg20170118
73. 高级, 张海江*, 方洪健,李楠 (2017),一种高效的基于交叉梯度结构约束的三维地震走时与直流电阻率联合反演策略,地球物理学报,60(9), 3628-3641,doi:10.6038/cjg2017090
72. Zhang, H*. R.M. Nadeau and H. Guo (2017), Imaging the Nonvolcanic Tremor Zone Beneath the San Andreas Fault at Cholame, California using Station-Pair Double-Difference Tomography, Earth and Planetary Science Letters, 460,76–85.
71. Guo, H. and Zhang H.* (2017), Development of double-pair?double difference?earthquake location algorithm for improving earthquake locations, Geophysical Journal International, 208, 333–348, doi: 10.1093/gji/ggw397.
70. Chen, Yukuan, H. Zhang*, Y. Miao, Y. Zhang, Q. Liu (2017), Back azimuth constrained double-difference seismic location and tomography for downhole microseismic monitoring, Physics of the Earth and Planetary Interiors, 264, 35-46, doi:10.1016/j.pepi.2016.10.003.
2016
69. 高级,张海江*(2016),不同观测方式下基于伴随矩阵的2.5D全通道电阻率反演研究,地球物理学进展, 31(6), 2534-2540, doi: 10.6038/pg2016062
68. Xiang, S., and H. Zhang* (2016), Efficient Edge-Guided Full Waveform Inversion by Canny Edge Detection and Bilateral Filtering Algorithms, Geophysical Journal International, doi: 10.1093/gji/ggw314
67. 胡景,钱佳威,郭浩,王康东,翟秋实,张海江*,姚华建,张伟,安美建 (2016),基于长江安徽段气枪主动源实验庐江台阵的台站对双差地震速度成像,中国地震32(2):343-355
66. Lin Y., and H. Zhang* (2016), Imaging hydraulic fractures by microseismic migration for downhole monitoring system, Physics of the Earth and Planetary Interiors, doi:10.1016/j.pepi.2016.06.010
65. Zhang, Jiewen, H. Zhang*, Y. Zhang, and Q. Liu (2016), Fast one-dimensional velocity model determination for microseismic monitoring using station-pair differential arrival times based on the differential evolution method, Phys. Earth Planet. In., doi: 10.1016/j.pepi.2016.06.003
64. 常凯,张海江*,林叶(2016),基于样条插值与曲波变换压缩感知的井下微地震监测数据重建, 物探化探计算技术,Vol. 38,No.6.
63. 高级,张海江*(2016),基于交叉梯度交替结构约束的二维地震走时与全通道直流电阻率联合反演研究,地球物理学报,59(11), 4310-4322, doi: 10.6038/cjg20161131.
62. Li, Cheng, Huajian Yao*, Hongjian Fang, Xianliang Huang, Kesong Wan, Haijiang Zhang, Kangdong Wang (2016), 3D Near-surface shear-wave velocity structure from ambient-noise tomography and borehole data in the Hefei urban area, China, Seismological Research Letters, DOI: 10.1785/0220150257
61. Fang, Hongjian, Haijiang Zhang*, Huajian Yao, Amir Allam, Dimitri Zigone, Yehuda Ben-Zion, Clifford Thurber, Robert van der Hilst (2016), A new three-dimensional joint inversion algorithm of body-wave and surface-wave data and its application to the Southern California Plate Boundary Region, Journal of Geophysical Research-Solid Earth. 121, doi:10.1002/2015JB012702
60. Ellen Syracuse, Monica Maceira, Germán A Prieto, Haijiang Zhang, Charles J Ammon (2016), Multiple plates subducting beneath Colombia, as illuminated by seismicity and velocity from the joint inversion of seismic and gravity data, Earth and Planetary Science Letters,444, Pages 139–14
2015
59. Bennington, N.L., H. Zhang, C.H. Thurber, and P. A. Bedrosian (2015), Joint inversion of seismic and magnetotelluric data in the Parkfield region using the cross-gradient constraint, Pure and Applied Geophysics, doi: 10.1007/s00024-014-1002-9, 172(5): 1033-1052.
58. 张佩, 张海江*, 刘影, 王华, M. Nafi Toksoz (2015), 美国Cove Fort-Sulphurdale地热区地震震源机制和各向异性研究,地震学报,37(6): 899-915, doi:10.11939/jass.2015.06.002 [Zhang P., Zhang H.J.*, Liu Y., Wang H., Toksoz M.N., (2015), Focal mechanisms and seismic anisotropy analysis of local earthquakes at the Cove Fort Surphurdale geothermal site, United States, Acta Seismologica Sinica, 37(6), 899-915, doi:10.11939/jass.2015.06.002,(in Chinese)]
57. Liu Y., H. Zhang*, X. Zhang, S. Pei, M. An, and S. Dong (2015), Anisotropic upper crust above the aftershock zone of the 2013 Ms 7.0 Lushan Earthquake from the shear wave splitting analysis, Geochemistry, Geophysics, Geosystems (G-cubed), 16, doi:10.1002/2015GC005972.
56. Zhang, X., and H. Zhang* (2015), Near real-time travel time tomography method and its application in imaging the Etna volcano in Italy, Journal of Geophysical Research, Solid Earth, 120, doi:10.1002/2015JB012182.
55. Sandra Bourguignon, Stephen Bannister, C. Mark Henderson, John Townend, Haijiang Zhang (2015), Structural heterogeneity of the midcrust adjacent to the central Alpine Fault, New Zealand: Inferences from seismic tomography and seismicity between Harihari and Ross, Geochemistry, Geophysics, Geosystems, doi: 10.1002/2014GC005702.
54. Lin Y., E. M. Syracuse, M. Maceira, H. Zhang, and C. Larmat (2015), Double-Difference Travel-Time Tomography with Edge-Preserving Regularization and a Priori Interfaces, Geophysical Journal International, 201 (2):574-594.doi: 10.1093/gji/ggv047
53. Syracuse, E. M. , M. Maceira, H. Zhang, and C.H. Thurber (2015), Seismicity and structure of Akutan and Makushin Volcanoes, Alaska, using joint body- and surface-wave tomography, Journal of Geophysical Research-Solid Earth, 120, doi:10.1002/2014JB011616。
52. Fang, Hongjian, Huajian Yao, Haijiang Zhang, Yu-Chih Huang, and Rob van der Hilst (2015), Direct inversion of surface wave dispersion for 3-D shallow crustal structure: methodology and application to Taipei Basin, Geophysical Journal International, 201 (3): 1251-1263. doi: 10.1093/gji/ggv080
2014
51. Froment B., J.J. McGuire, R.D. van der Hilst, P. Gouedard, E.C. Roland, H. Zhang, and J.A. Collins (2014), Imaging along-strike variations in mechanical properties of the Gofar transform fault, East Pacific Rise, Journal of Geophysical Research,119, 7175–7194, doi:10.1002/2014JB011270.
50. Zhang Jie, Haijiang Zhang, Enhong Chen, Yi Zheng, Wenhuan Kuang, Xiong Zhang (2014), Real-time earthquake monitoring using a search engine method, Nature Communications, 5:5664 doi: 10.1038/ncomms6664 (http://www.nature.com/ncomms/2014/141204/ncomms6664/full/ncomms6664.html)
49. Fang, H., and H. Zhang* (2014), Wavelet-based double-difference seismic tomography with the sparsity regularization, Geophys. J. Int., 199, 944–955, doi: 10.1093/gji/ggu305. (Corresponding author)
48. Bennington, N.L., H. Zhang, C.H. Thurber, and P. A. Bedrosian (2014), Joint inversion of seismic and magnetotelluric data in the Parkfield region using the cross-gradient constraint, Pure and Applied Geophysics, doi: 10.1007/s00024-014-1002-9, Published online 14 December 2014
47. Pei, S.*, H. Zhang*, J. Su, and Z. Cui (2014), Ductile Gap between the Wenchuan and Lushan Earthquakes Revealed from the Two-dimensional Pg Seismic Tomography, Scientific Reports 4, 6489; DOI:10.1038/srep06489. (Corresponding author)
46. He, R., X. Shang, C. Yu, H. Zhang*, and R. D. van der Hilst (2014), Detailed Moho Depth Mapping of Continental China by Receiver Function Analysis, Geophysical Journal International,199, 1910–1918, doi: 10.1093/gji/ggu365
45. Zeng, X., H. Zhang*, X. Zhang, H. Wang, Y. Zhang, Q. Liu (2014), Surface Microseismic Monitoring of Hydraulic Fracturing of a Shale-Gas Reservoir Using Broadband Seismic Sensors, Seismological Research Letters, 85, 668-677, doi: 10.1785/0220130197. (Corresponding author).
44. Zhang, H., M. Maceira , P. Roux and C.H. Thurber, (2014), Joint Inversion of Body-Wave Arrival Times and Surface-Wave Dispersion for Three-Dimensional Seismic Structure Around SAFOD, Pure and Applied Geophysics, doi: 10.1007/s00024-014-0806-y, published online March 29, 2014.
43. Liao, P.-C., C.-C. Lii, U.-C. Lai, P.-Y. Chang, H. Zhang, and C. Thurber (2014), A GPU implementation and optimization for parallel double-difference seismic tomography, Bull. Seism. Soc. Am., 104, 10.1785/0120130121.
42. Li Z., H. Zhang*, and Z. Peng (2014), Structure-Controlled Seismic Anisotropy Along the Karadere-Düzce Branch of the North Anatolian Fault Revealed by Shear-wave Splitting Tomography, Earth Planet. Sci. Lett., doi:10.1016/j.epsl2014.01.046. (*Corresponding author)
41. Pesicek, J.D., H. Zhang, and C.H. Thurber (2014), Multi-scale seismic tomography and earthquake relocation incorporating differential time data: Application to the Maule subduction zone, Chile, Bull. Seism. Soc. Am., 104, 10.1785/0120130121.
40. Han, L., X. Zeng, C. Jiang, S. Ni, H. Zhang, and L. Long (2014), Focal Mechanisms of the 2013 Mw 6.6 Lushan, China Earthquake and High-Resolution Aftershock Relocations, Seismological Research Letters, Vol. 85, doi: 10.1785/0220130083.
2013
39. Li, J., H. Zhang, W.L. Rodi, and M.N. Toksoz (2013), Joint microseismic location and anisotropic tomography using differential arrival times and differential backazimuths, Geophys. J. Int., doi: 10.1093/gji/ggt358.
38. Bennington, N. L., C. Thurber, Z. Peng, H. Zhang, and P. Zhao (2013), Incorporating fault zone head wave and direct wave secondary arrival times into seismic tomography: Application at Parkfield, California, J. Geophys. Res., Solid Earth, 118, 1008–1014, doi: 10.1002/jgrb.50072.
2012
37. Haijiang Zhang, Gasperikova, E., Parker B., Gudmundsson O., Seher T., Newman G., Fehler, M., Arnason K. Advanced 3D Geophysical Imaging Technologies for Geothermal Resource Characterization, Geothermal Resources Council Transactions, 36, 2012/9/27-2012/10/3, pp 843-848, 2012.
36. Westman, E.C.; Luxbacher, K.D.; Schafrik, S.J.; Swanson, P.I.; Zhang, H.Time-lapse passive seismic velocity tomography of longwall coal mines: A comparison of methods, 46th US Rock Mechanics / Geomechanics Symposium 2012, 24/6/2012-27/6/2012, pp 602-607, Chicago, IL, United states, 2012.
35. Sun, A., Y. Sun, H. Zhang and D. Yu (2012), 1-D P and S-wave velocity models for the collision zone between the northern Tianshan m ountain and the Junggar basin based on local earthquake data, Earthq. Sci., 25, 495–503, doi:10.1007/s11589-012-0873-z.
2011
34. Seher, Tim; Zhang, Haijiang; Fehler, Mike; Yu, Haiying; Soukhovitskaya, Veronika; Commer, Michael; Newman, Gregory, Temporal velocity variations beneath the Coso geothermal field observed using seismic double difference tomography of compressional and shear wave arrival times, Geothermal Resources Council Transactions, pp 1743-1746, 2011.
33. Bannister, S, B. Fry, M. Reyners, J. Ristau and H. Zhang (2011), Fine-scale relocation of aftershocks of the 22 February Mw 6.2 Christchurch earthquake, using double-difference tomography, Seismological Research Letters, 82, 839-845.
32. Li, J., H. Zhang, H.S. Kuleli, and M.N. Toksoz (2011), Focal mechanism determination using high frequency full waveform matching and its application to small magnitude induced earthquakes, Geophy. J. Int., doi: 10.1111/j.1365-246X.2010.04903.x.
31. Li, J., K. S. Kuleli, H. Zhang, and M.N. Toksoz (2011), Focal mechanism determination of induced microearthquakes in an oil field using full waveforms from shallow and deep seismic networks, Geophysics, 76, WC87.
2010
30. Zhang, H., R.M. Nadeau, and M.N Toksoz (2010), Locating nonvolcanic tremors beneath the San Andreas Fault using station-pair double-difference location method, Geophys. Res. Lett., 37, L13304, doi:10.1029/2010GL043577.
29. Lin, G., C.H. Thurber, H. Zhang, E. Hauksson, P.M. Shearer, F. Waldhauser, T.M. Brocher, and J. Hardebeck (2010), A California statewide three-dimensional seismic velocity model from both absolute and differential times, Bull. Seismol. Soc. Am., 100, 225-240, doi:10.1785/0120090028.
28. Pei, S., J. Su, H. Zhang, Y. Sun, M.N. Toksoz, Z. Wang, J. Zhao, and H. Liu (2010), Three-dimensional seismic velocity structure across the 2008 Wenchuan Ms8.0 earthquake, Sichuan, China, Tectonophysics, 491, 211-217, 10.1016/j.tecto.2009.08.039.
27. Pesicek, J.D., C.H. Thurber, H. Zhang, H.R. DeShon, E.R. Engdahl, and S. Widiyantoro (2010), Teleseismic Double-Difference Relocation of Earthquakes along the Sumatra- Andaman Subduction Zone using a Three-Dimensional Model, J. Geophy. Res., 115, B10303, doi:10.1029/2010JB007443.
26. Pesicek, J.D., C.H. Thurber, S. Widiyantoro, H. Zhang, H.R. DeShon, and E.R. Engdahl (2010), Sharpening the Tomographic Image of the Subducting Slab below Sumatra, the Andaman Islands, and Burma, Geophys. J. Int., 182, 433-453, 10.1111/j.1365-246X.2010.04630.x
25. Song, F., H.S. Kuleli, M.N. Toksoz, E. Ay, and H. Zhang (2010), An improved method for hydrofracture event detection and phase picking, Geophysics, 75, A47, doi:10.1190/1.3484716.
2009
24. Zhang, H., P. Wang, R.D. van der Hilst, M.N. Toksoz, C. Thurber, and L. Zhu (2009), Three-dimensional Passive Seismic Waveform Imaging around the SAFOD site, California, Using the Generalized Radon Transform, Geophys. Res. Lett., 36, L23308, doi: 10.1029/2009GL040372.
23. Zhang, H., C.H. Thurber, and P. Bedrosian (2009), Joint inversion for Vp, Vs, and Vp/Vs at SAFOD, Parkfield, California, Geochemistry, Geophysics, Geosystems, 10, Q11002, doi:10.1029/2009GC002709.
22. Zhang, H., S. Sarkar, M.N. Toksoz, H.S. Kuleli, and F. Al-Kindy (2009), Passive seismic tomography using induced seismicity at a petroleum field in Oman, Geophysics, 74(6), WCB67, doi:10.1190/1.3253059.
21. Thurber, C., H. Zhang, Brocher, T., and V. Langenheim (2009), Regional three-dimensional seismic velocity model of the crust and uppermost mantle of northern California, J. Geophys. Res., 114, B01304, doi:10.1029/2008JB005766.
2008
20. Li, C., L. Huang, N. Duric, H. Zhang, and C. Rowe (2008), An improved automatic time-of-flight picker for medical ultrasound tomography, Ultrasonics, doi:10.1016/j.ultras.2008.05.005.
19. Pesicek, J., C. Thurber, H. DeShon, S. Prejean, H. Zhang (2008), Three-Dimensional P-wave Velocity Structure and Precise Earthquake Relocation at Great Sitkin Volcano, Andreanof Islands, Alaska, Bull. Seism. Soc. Am., 98, 2428 - 2448.
18. Liu, Y., H. Zhang, C. Thurber, and S. Roecker (2008), Shear wave anisotropy in the crust around the San Andreas fault near Parkfield: spatial and temporal analysis, Geophys. J. Int., 172, 957-970.
2007
17. Zhang, H., Y. Liu, C. Thurber, and S. Roecker (2007), Three-dimensional shear-wave splitting tomography in the Parkfield, California Region, Geophys. Res. Lett., 34, L24308, doi:10.1029/ 2007GL03195.
16. Zhang, H. and C.H. Thurber (2007), Estimating the model resolution matrix for large-seismic tomography problems based on Lanczos bidiagonalization with partial reorthogonalization, Geophys. J. Int., 170, 337-345.
15. Thurber, C.H., T.M. Brocher, H. Zhang, and V.E. Langenheim (2007), Three-dimensional P wave velocity model for the San Francisco Bay region, California, J. Geophys. Res.,112, B07313, doi:10.1029/2006JB004682.
Scarfi, L., E. Giampiccolo, C. Musumeci, D. Patanè, and H. Zhang (2007), New insights on 3D crustal structure in Southeastern Sicily (Italy) and tectonic implications from an adaptive mesh seismic tomography, Phys. Earth Planet. Interiors, 161, 74-95, doi:10.1016/j.pepi.2007.01.007.
14. Okada, T., A. Hasegawa, J. Suganomata, N. Umino, H. Zhang, and C. Thurber (2007), Imaging the heterogeneous source area of the 2003 M6.4 northern Miyagi earthquake, NE Japan, by double-difference tomography, Tectonophysics, 430(1-4), 67-81.
13. Okada, T., A. Hasegawa, J. Suganomata, D. Zhao, H. Zhang, and C. Thurber (2007), Imaging the source area of the 1995 southern Hyogo (Kobe) earthquake (M7.3) using double-difference tomography, Earth Planet. Sci. Lett., 253 (1-2), 143-150, doi:10.1016/j.epsl.2006.10.022.
2006
12. Shelly, D., G. C. Beroza, H. Zhang, C. Thurber, and S. Ide (2006), High-resolution subduction zone seismicity and velocity beneath Ibaraki prefecture, Japan, J. Geophys. Res., 111, doi:10.1029/2005JB004081.
11. Thurber, C., H. Zhang, F. Waldhauser, J. Hardebeck, and A. Michael (2006), Three-dimensional compressional wavespeed model, earthquake relocations, and focal mechanisms for the Parkfield, California, region, Bull. Seism. Soc. Am., 96(4B), S38-S49, DOI: 10.1785/0120050825.
10. Okada T., T. Yaginuma, N.Umino, T. Matsuzawa, A.Hasegawa, H. Zhang and C.H. Thurber (2006), Detailed imaging of the fault planes of the 2004 Niigata–Chuetsu, central Japan, earthquake sequence by double-difference tomography, Earth Planet. Sci. Lett., 244 (1-2), 32-43, doi:10.1016/j.epsl.2006.02.010.
9. Zhang, H., and C. Thurber (2006), Development and applications of double-difference tomography, Pure and Applied Geophys., 163, 373-403, doi:10.1007/s00024-005-0021-y.
2005
8. Zhang, H., and C. Thurber (2005), Adaptive-mesh seismic tomography based on tetrahedral and Voronoi diagrams: Application to Parkfield, California, J. Geophys. Res., 110, B04303, doi:10.1029/2004JB003186.
7. Okada, T, et al. (2005), Aftershock distribution and 3D seismic velocity structure in and around the focal area of the 2004 mid Niigata prefecture earthquake obtained by applying double-difference tomography to dense temporary seismic network data, Earth, Planets, and Space, 57, 435-440.
2004
6. Zhang, H., C. H. Thurber, D. Shelly, S. Ide, G. C. Beroza, A. Hasegawa, High-resolution subducting-slab structure beneath northern Honshu, Japan, revealed by double-difference tomography (2004), Geology, 32, 361-364, doi: 10.1130/G20261, 2004.
5. Du, W., C. H. Thurber, M. Reyners, D. Eberhart-Phillips, and H. Zhang (2004), New constraints on seismicity in the Wellington region of New Zealand from relocated earthquake hypocentres, Geophys. J. Int., 158, 1088-1102.
4. Thurber, C., S. Roecker, H. Zhang, S. Baher, and W. Ellsworth (2004), Fine-scale Structure of the San Andreas Fault and Location of the SAFOD Target Earthquakes, Geophys. Res. Lett., 31, doi:10.1029/2003GL019398.
3. Thurber, C., and H. Zhang (2004), Comment on 'The effect of velocity structure errors on double-difference earthquake location' by A. Michelini and A. Lomax, Geophys. Res. Lett., 31, L15613, doi 10.1029/2004GL020650.
2003
1. Zhang, H., and C. H. Thurber (2003), Double-Difference Tomography: The Method and Its Application to the Hayward Fault, California, Bull. Seism. Soc. Am, 93, 1875-1889.
2. Zhang, H., C. H. Thurber, C. A. Rowe (2003), Automatic first-arrival detection and picking with multiscale wavelet analysis, Bull. Seism. Soc. Am., 93, 1904-1912.