人才详细信息

姓名:何建坤
性别:
学历:博士
专家类别:研究员
电话:010-84097064
传真:010-8409 7079
电子邮箱:jkhe@itpcas.ac.cn
职称:研究员
通讯地址:北京市朝阳区林萃路16号院3号楼

简介

教育经历: 

1992-1996年:南京大学,构造地质与地球物理学,博士

1985-1988年:中国矿业大学,构造地质学,硕士

1981-1984年:中国矿业大学,构造地质学,学士

研究经历: 

2007 -至今,研究员,中国科学院青藏高原研究所

2008,3- 6,合作研究,Department of Earth and Space Sciences, University of California-Los Angeles, USA

2005,9-12,访问学者,Laboratoire de Geophysique, CNRS & Universite de Montpellier II, France

2004,7- 9,合作研究,Laboratoire de Geophysique, CNRS & Universite de Montpellier II, France

2002,7-12,访问学者,Department of Geological Sciences, University of Missouri-Columbia, USA

1998 – 2006,副研究员,中国科学院地质与地球物理研究所

1996-1998,博士后,中国科学院地球物理研究所

1988 – 1992,讲师,地质系,中国矿业大学

研究方向

岩石圈变形动力学数值模拟,地球动力学

职务

研究员

社会任职

中国力学学会地球动力学专业委员会委员 (2004-2007)

澳大利亚《Journal of the Virtual Explorer》编委 (2005- )

美国《International Journal of Geosciences》编委 (2011-)

承担项目

国家自然科学基金面上项目《汶川地震强余震触发机制的三维数值模拟研究》,2013-2016,课题负责人   

国家自然科学基金重点项目《喀喇昆仑和阿尔金断裂走滑与青藏高原南北走向正断层作用关系:从运动学观测到动力学模拟》,2011-2014,课题负责人   

中国科学院战略性先导科技专项(B类)子课题《青藏高原边界扩展机制的数值模拟》,2012-2017,子课题负责人   

中国科学院知识创新工程重要方向项目《青藏高原北缘大型走滑边界断裂系统的运动学观测和动力学模拟》,2011-2013,项目负责人   

中国科学院资源环境领域国际合作重点项目课题《帕米尔高原现代地壳变形与动力学》,2010-2013,课题负责人 

获奖及荣誉

代表论著

1. He, J., P. Vernant, J. Chéry, W. Wang, et al., 2013, Nailing down the slip rate of the Altyn Tagh fault. Geophysical Research Letters, 40, 5382-5386.
2. He, J., S. Lu, W. Wang, 2013, Three-dimensional mechanical modeling of the GPS velocity field around the northeastern Tibetan plateau and surrounding regions. Tectonophysics, 584, 257-266.
3. He, J., W. Xia, and S. Lu, 2011, Three-dimensional finite element modeling of stress evolution around the Xiaojiang fault system, southeastern Tibet, in the past ~500 years. Tectonophysics, 507, 70-85.
4. He, J. and G. Peltzer, 2010, Poroelastic triggering in the January 9-22, 2008 Nima-Gaize (Tibet) earthquake sequence. Geology, 38(10), 907-910.
5. He, J., S. Lu, and X. Wang, 2009, Mechanical relation between crustal rheology, effective fault friction, and strike-slip distribution among the Xiaojiang fault system, southeastern Tibet. Journal of Asian Earth Sciences, 34, 363-375.
6. He, J. and J. Chéry, 2008, Late Quaternary slip rates of the Altyn Tagh,the Kunlun and the Karakorum faults (Tibet) from 3D mechanical modeling. Earth and Planetary Science Letters, 274; 50-58.
7. He, J. and S. Lu, 2007, Lower friction of the Xianshuihe-Xiaojiang fault system and its effect on active deformation around the southeastern Tibetan margin. Terra Nova, 19, 204-210.
8. He, J., Y. Li, et al., 2005, Asymmetric flank uplift of the Yinchuan graben, north central China: implication of lateral variation of crustal rheology from the Alashan to the Ordos. Geophysical Research Letters, 32; L2213., doi:10.1029/ 2003GL018764.
9. He, J., D. Cai, Y. Li, and Z. Gong, 2004, Active extension of the Shanxi rift, north China: does it result from anticlockwise block rotations?. Terra Nova, 16, 38-42.
10. He, J., M. Liu, and Y. Li, 2003, Is the Shanxi rift of northern China extending?. Geophysical Research Letters, 30, 2213, doi:10.1029/2003GL018764.
11. He, J., 2003, Mechanical instability of the crustal thickness transition zone between the Taihang Shan mountains in relation to the tectonic compression of the frontal Cenozoic basin. Chinese J. Geophys., 46, 712-724.
12. He, J., J. Liu, 2002, Lower-crust ductile flow and its mechanical relation with syn-collision crustal extension in orogenic belt. Chinese J. Geophys., 45, 502-516.
13. He, J., 1998,Morphology of the Moho discontinuity beneath the Eastern Qinling mountains and its implication for deep process of the collisional orogeny. Chinese J. Geophys., 41(supp); 64-76.
14. Zhao, L., X. Xie, J. He, et al., 2013, Crustal flow pattern beneath the Tibetan Plateau constrained by regional Lg-wave Q tomography. Earth and Planetary Science Letters, 383, 113-122.
15. Wang, X., J. He, et al., 2013, A possible mechanism for the initiation of the Yinggehai Basin: A visco-elasto-plastic model. Journal of Asian Earth Sciences, 74, 25-36.
16. Wang, X., and J. He, 2012, Channel flow of the lower crust and its relation to large-scale tectonic geomorphology of the eastern Tibetan Plateau. Science in China (D), 55, 1-8.
17. Pei, S., J. Su, H. Zhang,Y. Sun, M. N. Toks?z, Z. Wang, X. Gao, J. Liu, J. He, 2010, Three-dimensional seismic velocity structure across the 2008 Wenchuan Ms8.0 earthquake, Sichuan, China. Tectonophysics, 491, 211-217.
18. Pei, S., Z. Cui, Y. Sun, M. N. Toks?z, C.A. Rowe, X. Gao, J. Zhao, H. Liu, J. He, F. D. Morgan, 2009, Structure of the Upper Crust in Japan from S-wave Attenuation Tomography. Bulletin of the Seismological Society of America, 99(1), 428-434.
19. Wang, J., Z. Ye, and J. He, 2008, Three-dimensional mechanical modeling of large-scale crustal deformation in China constrained by the GPS velocity field. Tectonophysics, 446, 51-60.
20. Chang, X., Y. Liu, and J. He, 2007, Lower velocities beneath the Taihang Mountains, northeastern China. Bulletin of the Seismological Society of America, 97, 1364-1369.
21. Li, Y., J. Zhang, J. He, et al., 2007, Current-day tectonic motion and intraplate deformation strain field obtained from space geodesy in the Pacific Plate. Chinese J. Geophys., 50, 437-447.
22. Liu, Y., C. Chang, J. He, 2005, Three-dimensional velocity images of the crust and upper mantle beneathe the north-south zone in China. Bulletin of the Seismological Society of America, 95, 916-926.
23. Sun, R., F. Liu, and J. He, 2001, Structural setting of strong earthquakes in the Huabei area of China. Pure and Applied Geophysics, 158, 903-918.
24. Liu, J., F. Liu, J. He, H. Chen, and Q. You, 2001, Study of seismic tomography in Panxi paleorift area of southwestern China—Structural features of crust and mantle and their evolution. Science in China (D), 44, 277-288.
25. Cai, D., Y. Luo, C. Yao, J. He, et al., 2000, Structures of the Bohai petroliferous area, Bohai Bay Basin. Acta Geologica Sinica, 74(3), 641-650.
26. 何建坤, 2013, 构造地质中的数值模拟方法. 见: 丁仲礼(主编), 固体地球科学研究方法. 北京:科学出版社, 969-980. 
国际会议摘要:
27. He, J., P. Vernant, W. Wang, et al., 2011, A new GPS network across the Altyn Tagh Fault of the Tibetan plateau: preliminary results from 3-years’ survey, Abstract T51B-2336 presented at 2011 Fall Meeting, AGU, San Francisco, Calif., 5-9 Dec (Poster).
28. He, J., S. Lu, and W. Wang, 2010, Strain accumulation across the Longmen Shan before the 2008 Mw 7.9 Wenchuan earthquake. Abstract T43C-2231 presented at 2010 Fall Meeting, AGU, San Francisco, Calif., 13-17 Dec (Poster).
29. Wang, W., P. Vernant, J. He*, et al., 2009, New GPS Network across the Altyn Tagh Fault, preliminary results from the first survey. EOS Trans. AGU, 90(52), Fall Meet. Suppl., Abstract T21B-1792 (Poster).
30. He, J. and G. Peltzer, 2009, Poroelastic triggering in the January 9-22, 2008 Nima-Gaize (Tibet) earthquake sequence. EOS Trans. AGU, 90(52), Fall Meet. Suppl., Abstract S51C-1434 (Poster).
31. Peltzer, G. and J. He, 2009, Fault permeability and poroelastic triggering in the January 9-22, 2008 Nima-Gaize (Tibet) earthquake sequence. FRINGE, 2009 workshop, ESA, Italy (Oral).
32. He, J. and G. Peltzer, 2008, The 2008/01/09-22 Ms=6.4-5.4 earthquakes in southern central Tibet from InSAR observations and numerical modeling. EOS Trans. AGU, 89(53), Fall Meet. Suppl., Abstract T24A-03 (Oral).
33. He. J., S. Lu., and X. Wang, 2007,Coulomb stress change on the Xiaojiang and the Red River faults, southeastern Tibetan Plateau, from the 1970 Ms=7.7 Tonghai earthquake. EOS Trans. AGU, 88(52), Fall Meet. Suppl., Abstract T43B-1353 (Poster).
34. He, J., 2006, Strike-slip motion of the Xiaojiang fault system, southeastern Tibet, driven by lower-crust flow. EOS Trans. AGU, 87(36), West. Pac. Geophys. Meet. Supple., Abstract T21B-05 (Invited Oral).
35. He, J., Y. Li, and C. Teng, 2004, Three-dimensional Mechanical Modeling of the GPS Velocity Field around the Northeastern Tibet and Surrounding Region. EOS Trans. AGU, 85(47), T11cC1276 (Poster).
36. He, J. M. Liu, et al., 2002, Intraplate seismicity and crustal deformation in the North China block: Role of crustal heterogeneities. EOS Trans. AGU, 83(47), Fall Meet. Suppl., Abstract S21B-0998 (Poster).
37. >>>>主要实验设备有20套大地测量型GPS和1台高性能DELL并行计算机(20 CPU/80计算内核),用于野外观测、室内数据处理和岩石圈变形三维动力学数值模拟等。硕士和博士研究生可选方向:1)GPS/InSAR大地测量与活动构造、2)地震触发机制与断裂相互作用、3)地壳/岩石圈变形动力学数值模拟