唐跟阳,男,博士,教授,博士生导师,中国石油大学(北京)地球物理学院副院长。
江苏赣榆县人,本科毕业于北京大学地球物理系,博士毕业于英国剑桥大学地球科学系,从事地球物理和地质资源与地质工程专业,研究领域包括地震岩石物理与地震波传播理论及其应用。在学习期间曾在中石油塔里木油田公司勘探开发研究院、斯伦贝谢剑桥研发中心以及英国国家海洋研究中心实习,2012年10月入职中国石油大学(北京),2013年6月入选学校“青年拔尖人才”,并晋升为副教授。为欧洲地球物理学家与工程师学会EAGE会员、EAGE北京分会秘书长、美国勘探地球物理学会SEG会员、SEG大学与学生委员会CUSP委员会委员。
联系方式
Email: tanggenyang@163.com 办公电话:010-89731581
通讯地址:北京市昌平区府学路18号中国石油大学(北京)102249
教育背景
2002.9-2006.6 北京大学地球物理系获学士学位
2006.9-2007.12 北京大学地球物理系硕士项目学习
2007.10 获英国工程与物理研究理事会颁发的Dorothy Hodgkin Postgraduate Awards
2008.1-2012.2 英国剑桥大学地球科学系获博士学位
奖励和荣誉
2007.10 获英国工程与物理研究理事会颁发的Dorothy Hodgkin Postgraduate Awards
2013.6 获中国石油大学(北京)“青年拔尖人才”称号
2016.11 中国石油与化学工业联合会科技进步二等奖(排名本单位第5)
研究方向
[1]岩石物理与地震波正反演
[2]多尺度构造地震建模与成像
[3]地下空间探测与流体检测
学术兼职
[1] 《Geophysical Prospecting》副主编
[2] 《Exploration Geophysics》副主编
[3] 《石油科学通报》副主编
科研项目
共主持国家级、省部级科研项目3项,校级科研项目2项,参与国家级、省部级科研项目5项,包括国家973项目子课题1项、中石油十三五子课题1项、中石油十二五项目子课题2项、国家自然科学基金项目2项。
主持项目:
⑴ 《致密砂岩多频段岩石物理特征与流体检测应用》(41774143),2018.1-2021.12,自然科学基金(面上)项目,主持
⑵ 《储层岩石实验室地震频段测试与分析》,2016.10-2017.9,中石化横向项目
⑶ 《苏门答腊俯冲带分段边界弧前区的精细结构研究》(41304042),2014.1-2016.12,自然科学基金(青年)项目,主持
⑷ 《苏门答腊俯冲带地震断层分段机理研究》,2014.1-2016.12,教育部留学归国人员启动基金,主持
⑸ 《非均质岩石中弹性波传播的跨频段实验模拟与理论研究》(2462013BJRC004),2013.7-2016.6,中国石油大学(北京)拔尖人才基金,主持
⑹ 《苏门答腊俯冲带地震断层分段机理研究》(YJRC-2013-33),2013.1-2015.12,中国石油大学(北京)引进人才基金,主持
参与项目包括:
《深层温压条件下非均质岩石中多频段弹性波传播》(2013CB228601),2013-2017,国家重点基础研究发展规划973项目《深层油气藏地球物理探测的基础研究》(2013CB228600)子课题,
《物探新方法新技术研究》子课题《复杂介质地震岩石物理分析》,2013-2015,中石油集团公司十二五计划项目
《物探新方法新技术研究》子课题《非均质储层低频地震响应特征研究及应用》、还是《非均质储层全频带地震岩石物理分析方法研究及应用》,2011-2013,中石油集团公司十二五计划项目
《低频地震岩石物理系统测试与理论研究》,2017-2018,中国石油化工股份有限公司胜利油田分公司物探研究院勘探开发项目,合同编号:30200020-17-ZC0607-0003
《深层非常规能源物探新方法新技术》子课题《深层致密砂岩储层岩石物理实验测量与分析》,2017.4 -2018.9,中石油集团公司十二五计划项目,合同编号:
代表性论文
[1] Tang GY, Guo FH, Wang SX, et al., An upscaling numerical modeling of the squirt flow mechanism and effects of microcrack properties. Exploration Geophysics, 2021 (in press)
[2] Han X, Wang SX , Tang GY, Dong CH,He YH,Liu T,Zhao LM,Sun C , et al., Coupled effects of pressure and frequency on velocities of tight sandstones saturated with fluids: measurements and rock physics modelling[J]. Geophysical Journal International, 226(2), 1308–1321,2021(通讯作者)
[3] Sun C, Tang GY, Fortin J., Borgomano J. V. M. & Wang SX. Dispersion and Attenuation of Elastic Wave Velocities: Impact of Microstructure Heterogeneity and Local Measurements. Journal of Geophysical Research: Solid Earth, 125(12), e2020JB020132,2020(共同通讯)
[4] 唐跟阳,董春晖,王尚旭,曾心 ,任保德,基于差异共振声谱仪多阶共振模式的弹性模量频散测量,石油科学通报,5(4),483-495,2020
[5] Liang J , Mueller T M , Tang GY , et al. Compensating elastic transmission losses for P-wave attenuation estimation from sonic logs. Geophysical Prospecting, 67(4):969-983,2019
[6] Meng X, Wang S, Tang G, et al. Stochastic parameter estimation of heterogeneity from crosswell seismic data based on the Monte Carlo radiative transfer theory. Journal of Geophysics & Engineering, 2017, 14(3):621-633.(SCI,通讯作者)
[7] Meng X, Wang S, Tang G, et al. Monte-Carlo radiative transfer simulation of acoustic waves in two-dimensional random media and its application. Petroleum Science Bulletin, 2017.
[8] Li J, Wang S, Yang D, et al. Subsurface attenuation estimation using a novel hybrid method based on FWE function and power spectrum[J]. Exploration Geophysics, 2017.(SCI,通讯作者)
[9] Tang, G.*, P. J. Barton, L. C. McNeill, T. J. Henstock, F. Tilmann, S. M. Dean, M. D. Jusuf, Y. S. Djajadihardja, H. Permana, F. Klingelhoefer, and H. Kopp, 3-D active source tomography around Simeulue Island offshore Sumatra: Thick crustal zone responsible for earthquake segment boundary, Geophysical Research Letters, v. 40, pp. 48–53, 2013. (SCI一区,第一作者、通讯作者)
[10] Tang, G., Barton, P. J., Dean, S. M., Vermeesch, P. M., Jusuf, M. D., Henstock, T., Djajadihardja, Y., McNeill, L. C., Permana, H., 3-D Seismic Tomographic Inversion to Image Segmentation of the Sumatra Subduction Zone near Simeulue Island, Eos, Transactions of the American Geophysical Union, Fall Meeting Supplement, 90(52), 2009.
[11] Tang, G., Barton, P., Dean, S., Vermeesch, P., Jusuf, M. D., Henstock, T., Djajadihardja, Y. S., McNeill, L., Permana, H., 3-D Refraction Tomography in the Sumatra Subduction Zone,Eos, Transactions of the American Geophysical Union, Fall Meeting Supplement, 89(53), 2008.
[12] Zhao L, Tang G Y, Dong C H, et al. Effect of Strain-Gage-scale Inhomogeneity on Measuring Young's Modulus at Low Frequency. EAGE Conference and Exhibition. 2017.
[13] Sun C, Tang G Y, Dong C H, et al. Fluid Saturation Effect on the Characteristic Frequency and Attenuation of Tight Sandstone. EAGE Conference and Exhibition. 2017.
[14] Liang J, Müller T M, Tang G, et al. Towards Developing a Robust Q-extraction Method from Full-Waveform Acoustic Logs. EAGE Conference and Exhibition. 2017.
[15] Yin H, Zhao J, Tang G, et al. Pressure and Fluid Effect on Frequency Dependent Elastic Moduli in Fully Saturated Tight Sandstone. Journal of Geophysical Research Solid Earth, 2017. (SCI二区)
[16] Dong C, Tang G, Wang S, Y He. Numerical simulation and analysis for low frequency rock physics measurements. Journal of Geophysics & Engineering, 2017, 14(5). (SCI)
[17] Yin H, Zhao J, Tang G, et al. Numerical and experimental investigation of a low-frequency measurement technique: differential acoustic resonance spectroscopy. Journal of Geophysics & Engineering, 2016, 13(3):342-353. (SCI)
[18] 未晛,王尚旭,赵建国,唐跟阳,邓继新.含流体砂岩地震波频散实验研究.地球物理学报, 2015, 58(9):3380-3388.(SCI)
[19] Tang G., J. Zhao, X. Tong, and S. Wang, Estimating Compressibility and Density of Oil-Saturated Rock Samples Using Higher Order Resonance Modes of DARS, EAGE Expanded Abstract, 2013.
[20] J. Zhao, G. Tang, J. Deng, X. Tong, and S. Wang, Determination of rock acoustic properties at low frequency: A differential acoustical resonance spectroscopy device and its estimation technique, Geophysical Research Letters, v. 40, pp. 1-8, 2013. (SCI 二区)
[21] Deng J, Wang S, Tang G, et al. The influence of mesoscopic flow on the P-wave attenuation and dispersion in a porous media permeated by aligned fractures. Studia Geophysica Et Geodaetica, 2013, 57(3):482-506. (SCI)
[22] Dong C, Wang S, Zhao J, Tang G. Numerical experiment and analysis of the differential acoustic resonance spectroscopy for elastic property measurements. Journal of Geophysics & Engineering, 2013, 10(5):054002. (SCI)
[23] Chai X, Tang G, Peng R, et al. The Linearized Bregman Method for Frugal Full-waveform Inversion with Compressive Sensing and Sparsity-promoting. Pure & Applied Geophysics, 2017:1-17. (SCI)
[24] Chai X, Wang S, Tang G. Sparse reflectivity inversion for non-stationary seismic data with surface-related multiples: Numerical and field data experiments. Geophysics, 2017:1-125. (SCI)
[25] Chai X, Wang S, Tang G, et al. Stable and efficient Q -compensated least-squares migration with compressive sensing, sparsity-promoting, and preconditioning. Journal of Applied Geophysics, 2017, 145. (SCI)
[26] Yang J, Tao L, Tang G, et al. Modeling seismic wave propagation within complex structures. 应用地球物理(英文版), 2009, 6(1):30-41. (SCI)