Xiangyang LI

Li Xiangyang, male, was born in October 1962 in Lianhua County, Jiangxi Province. Chief Scientist of CNPC Key Laboratory of Geophysical Exploration, Distinguished Professor of China University of Petroleum (Beijing), Doctoral Supervisor. 1978 - In 1982, he studied at the Changchun Institute of Geology and obtained a bachelor's degree. From 1982 to 1984, he obtained a master's degree from the Graduate School of Beijing East China Petroleum Institute. From 1984 to 1987, he was the lecturer of the Department of Exploration at the East Campus of the East China Petroleum Institute. In 1988, he was sent to study in the UK and was a visiting scholar at the British Geological Survey (BGS). In the same year, he was awarded a doctoral scholarship by the British Environmental Resources Research Council (NERC) and a Ph.D. from the University of Edinburgh in 1991. In 1992, he worked for the British Geological Survey, and served as an associate researcher, researcher, senior researcher, chief researcher, special senior researcher, and research director. 2007 - 2010, Professor of Multi-wave Seismology at the University of Edinburgh, UK.

Professor Li Xiangyang is an internationally renowned geophysicist, a well-known scholar of seismic anisotropy theory, and an expert in multi-wave seismic exploration and fracture prediction. The Edinburgh Anisotropy Research Laboratory (EAP), led by Professor Li Xiangyang, is an internationally renowned academic research consortium. It has been engaged in seismic anisotropy, multi-wave seismic exploration and fracture prediction for 30 years. It is the only earthquake in the world. The international academic innovation team, which is the subject of research on seismic anisotropy, has received continuous funding from a number of international oil companies, and has conducted extensive research on seismic anisotropy theory and its application in petroleum exploration and development, in major international conferences and internationally authoritative academic journals. Published more than 200 papers.

Professor Li Xiangyang has a long-term cooperative relationship with academia and the petroleum industry. He was awarded the International Science and Technology Cooperation Award of the People's Republic of China in 2007. Since 2009, with the China University of Petroleum (Beijing) as the lead unit, combined with Eastern Geophysical Corporation, Chuanqing Drilling Engineering Company, China Petroleum Exploration Institute Northwest Branch and other units, in the basic theory of multi-wave seismic exploration and fracture prediction, Methodology, software products, and field applications have been carried out, and a talent team combining production, learning, research, and use has been formed. During the "Eleventh Five-Year Plan", "Twelfth Five-Year Plan" and "Thirteenth Five-Year Plan", Professor Li Xiangyang was responsible for major national science and technology major projects, and undertook a number of scientific research projects such as the National Natural Science Foundation of China and the CNPC Group. Received a number of scientific and technological awards such as the SEG Outstanding Achievement Award, the National Science and Technology Progress Award and the Provincial Science and Technology Award.


Journal articles published in recent years:


2019

[1].Zhang, F., Zhang, T., and Li, X., 2019, Seismic amplitude inversion for the transversely isotropic media with vertical axis of symmetry: Geophysical Prospecting, 67, 2368-2385.

[2].Wang, L., Zhang, F., Li, X., Di, B., and, Zeng, L., 2019, Quantitative seismic interpretation of rock brittleness based on statistical rock physics: Geophysics, 84, IM63-IM75.

[3].Zhang, F., Zhang, T., and Li, X., 2019, Characterization of a shale-gas reservoir based on a seismic AVO inversion for VTI media and quantitative seismic interpretation: Interpretation, https://doi.org/10.1190/int-2019-0050.1.

[4].Liu, Z., Zhang, F. and Li, X., 2019, Elastic anisotropy and its influencing factors in organic-rich marine shale of southern China: Science China-Earth Science, https://doi.org/10.1007/s11430-019-9449-7.

[5].付欣, 张峰,李向阳, 2019, 基于改进反射系数近似方程的纵横波阻抗同步反演: 地球物理学报, 62(1), 1-13.

[6].Luo, C., Xiangyang Li*, Guangtan Huang, 2019, Pre-stack AVA inversion by using propagator matrix forward modeling[J]. Pure and Applied Geophysics, 176(10), 4445-4476.

[7].Cong Luo, Guangtan Huang, Xiangyang Li 2019, Q estimation by combining ISD with a LSR method based on shaping-regularized inversion[J]. IEEE Geoscience and Remote Sensing letter, , 16(9).1457-1460.

[8].Ding P, Wang D, Di G, Li X. Investigation of the Effects of Fracture Orientation and Saturation on the Vp/Vs Ratio and Their Implications. Rock Mech Rock Eng. 2019;52(9):3293-304. doi:10.1007/s00603-019-01770-3.


2018

[1] 侯思安, 张峰, 李向阳. 基于贝叶斯概率矩阵分解的地震数据重建算法[J]. 石油科学通报, 2018(2).

[2] 曹占宁, 李向阳, 孙绍寒,等. 基于岩石物理模型的转换横波分裂在碳酸盐岩裂缝储层预测中的应用[J]. 石油科学通报, 2018(1).

[3] Cao Z, Li X Y, Liu J, et al. Carbonate fractured gas reservoir prediction based on [4] P-wave azimuthal anisotropy and dispersion[J]. Journal of Geophysics & Engineering, 2018.

[5] Luo C, Li X, Huang G. Application of oil-water discrimination technology in fractured reservoirs using the differences between fast and slow shear-waves[J]. Journal of Geophysics & Engineering, 2017, 14(4):723-738.

[6] Luo C, Li X, Huang G. Hydrocarbon identification by application of improved sparse constrained inverse spectral decomposition to frequency-dependent AVO inversion[J]. Journal of Geophysics & Engineering, 2018, 15(4).

[7] Qin X, Li X Y, Chen S Q, et al. The modeling and analysis of frequency-dependent characteristics in fractured porous media[J]. Journal of Geophysics & Engineering, 2018.


2017

[1]Zhi L, Chen S Q, Song B, et al. Nonlinear PP and PS Joint Inversion Based on the Exact Zoeppritz Equations : A Two-Stage Procedure[J]. Journal of Geophysics & Engineering, 2017, 15(2).

[2]Zhang, F., Li, X., and Qian, K., 2017, Estimation of anisotropy parameters for shales based on an improved rock physics model, part 1: theory: Journal of Geophysics and Engineering, 14, 143-158.

[3]Luo C, Li X, Huang G. Application of oil–water discrimination technology in fractured reservoirs using the differences between fast and slow shear-waves[J]. Journal of Geophysics & Engineering, 2017, 14(4):723-738.

[4]秦喜林, 李向阳, 陈双全,等. 频变AVO反演在顺南地区碳酸盐岩裂缝型储层流体识别中的应用[J]. 石油科学通报, 2017, 2(3):344-354.

[5]Ding P, Di B, Wang D, Wei J, Li X (2017) Measurements of seismic anisotropy in synthetic rocks with controlled crack geometry and different crack densities. Pure Appl Geophys 174(5):1907-1922

[6]丁拼搏, 狄帮让, 魏建新, 王丁, 李向阳, 尹志恒 (2017) 不同尺度裂缝对弹性波速度和各向异性影响的实验研究. 地球物理学报 60(4):1538-1546


2016

[1]Chen S Q, Zeng L B, Ping H, et al. The application study on the multi-scales integrated prediction method to fractured reservoir description[J] Applied Geophysics, 2016, 13(1):80-92.

[2]Chen H F, Li X Y, Qian Z P, et al. Prestack migration velocity analysis based on simplified two-parameter moveout equation[J]. Applied Geophysics, 2016, 13(1):135-144.

[3]Zhang F, Li X Y. Exact elastic impedance matrices for transversely isotropic medium[J]. Geophysics, 2016, 81(2):C23-C37.

[4]Yan H, Yang L, Li X Y, et al. Acoustic VTI Modeling Using an Optimal Time-Space Domain Finite-Difference Scheme[J]. Journal of Computational Acoustics, 2017, 24(04):1650016-.

[5]Yan H, Yang L, Dai H, Li X Y. Implementation of Elastic Prestack Reverse-Time Migration Using an Efficient Finite-Difference Scheme[J]. Acta Geophysica, 2016, 64(5):1605-1625.

[6]Zhi L, Chen S, Li X Y. Amplitude variation with angle inversion using the exact Zoeppritz equations — Theory and methodology[J]. Geophysics, 2016, 81(2):N1-N15.

[7]李向阳, 王九拴. 多波地震勘探及裂缝储层预测研究进展[J]. 石油科学通报, 2016, 1(1).


2015

[1]Amalokwu, K.; Chapman, M.; Best, A.I.; Sothcott, J.; Minshull, T.A.; Li, X.-Y. Experimental observation of water saturation effects on shear wave splitting in synthetic rock with fractures aligned at oblique angles[J]. Geophysical Journal International, 2015,200 (1): 17-24.

[2]Guo, Z., Liu, C., Li, X.-Y. Lan, H.. An improved method for the modeling of frequency-dependent amplitude-versus-offset variations[J]. IEEE Geoscience and Remote Sensing Letters, 2015,12 (1): 63-67.

[3]Guo, Z., Liu, X., Fu, W., & Li, X. Modeling and analysis of azimuthal AVO responses from a viscoelastic anisotropic reflector[J]. Applied Geophysics, 2015, 12(3), 441-452.

[4]Yang L, Li X Y, Chen S Q. Application of the double absorbing boundary condition in seismic modeling[J]. Applied Geophysics, 2015, 12(1):111-119.

[5]Li Y, Guo Z Q, Liu C, et al. A rock physics model for the characterization of organic-rich shale from elastic properties[J]. Petroleum Science, 2015, 12(2):264-272.

[6]Guo Z, Li X Y. Azimuthal AVO signatures of fractured poroelastic sandstone layers[J]. Exploration Geophysics, 2015: 48(1).

[7]Chen S, Chapman M, Wu X, et al. The application of quantitative gas saturation estimation based on the seismic wave dispersion inversion[J]. Journal of Applied Geophysics, 2015, 120(6):81-95.

[8]Guo Z, Li X Y. Rock physics model-based prediction of shear wave velocity in the Barnett Shale formation[J]. Journal of Geophysics & Engineering, 2015, 12(3).

[9]Wang, Y., Chen, S., & Li, X. Anisotropic characteristics of mesoscale fractures and applications to wide azimuth 3D P-wave seismic data[J]. Journal of Geophysics and Engineering, 2015, 12(3).

[10]Amalokwu, K., Chapman, M., Best, A. I., Minshull, T. A., & Li, X. (2015). Water saturation effects on P-wave anisotropy in synthetic sandstone with aligned fractures[J]. Geophysical Journal International, 2015, 202(2): 1088-1095.

[11]Keran Qian, Feng Zhang, Shuangquan Chen, Xiangyang Li and Hui Zhang. A rock physics model for analysis of anisotropic parameters in a shale reservoir in Southwest China, Journal of Geophysics and Engineering, 2015, 13(1): 19-34.

[12]Yang, L., Wu, X., and Chapman, M.. Impacts of kerogen content and fracture properties on the anisotropic seismic reflectivity of shales with orthorhombic symmetry. Interpretation, 2015, 3(3): ST1-ST7.


Date: 2019-03-12