科研人员

Scientist

基本信息

姓名:姜效典
性别:女
出生年月:1961年4月
祖籍:黑龙江省尚志市
联系地址:山东省青岛市崂山区松岭路238号,邮编266100.
中国海洋大学海洋地球科学学院
联系电话:0086-532-66782071(OfficeC406),66782060/66782153(实验室)
电子邮箱:xdjiang@ouc.edu.cn
主页访问量:500

简历

· 学习经历

山东海洋学院,学士学位,中国青岛,1983.07
青岛海洋大学,硕士学位,中国青岛,1988.07
德国汉堡大学,博士学位,德国汉堡,2004.12

· 工作简历

1988-1990,青岛海洋大学,助教
1990-1992.12,青岛海洋大学,讲师
1993.01-1995.12,青岛海洋大学,副教授
1996.01-至今,中国海洋大学,教授
1997.04-1997.09,美国麻省理工学院,访问学者
1999.06-1999.11,美国加州大学,访问学者
2001.05-2004.12,德国汉堡大学,访问学者
2005.01,法国国家地球物理研究所,访问学者
2005-至今,中国海洋大学,博士生导师
2006-2011,中国海洋石油东海石油局,特聘专家
2011.01-2011.02,澳大利亚珀斯大学,访问学者

· 学术兼职

《Tectonophysics》reviewer
《Terra Nova》reviewer
《Journal of Asian Earth Sciences》reviewer
国家自然科学基金评审专家
国家“863”资源领域评审专家
美国地球物理学会,会员
欧洲地球物理学会,会员
美国石油地质学家协会,会员
中国地球物理学会, 会员

· 国家级出版社出版的重要专著

2002年,金煜,姜效典,编著,《岩石圈动力学》,北京:科学出版社.

主持的重要科研项目(仅列2006年以来)

1)国家重大研究计划重点支持项目,基于流体地球物理表征的新几内亚-所罗门弧俯冲起始动力学机制(91858215,2019-2022),项目主持人
2)国家自然科学基金重点项目,南海西北部盆地构造沉积特征对青藏高原隆升的响应(41530963,2016-2020),项目主持人
3)国家科技重大专项,深层宽频三维地震高精度采集处理技术(2016ZX05027-002-005,2016-2020),课题负责人
4)国家重点研发计划,声信号对极区冰层和海底的响应及其声学参数观测技术(2018YFC1405901,2018-2021),课题负责人
5)国家公益性行业科研专项,基于数字海洋的资料整合及其共享服务应用示范(201305029,2013-2016),项目主持人
6)国家高技术研究发展计划(863计划),海上复杂油藏储层识别的叠前低频反射技术(2008AA09Z302,2009-2011),课题负责人
7)国家高技术研究发展计划(863计划),东海陆架盆地深层致密砂岩气地球物理识别技术及产能快速评价(2014-2016),课题负责人
8)国家自然科学基金面上项目,红河断裂带海-陆岩石圈形变时空特征及演化机制(41176038,2012-2015),项目主持人
9)国家自然科学基金面上项目,青藏高原东缘岩石圈挠曲形变特征(40772124,2010-2012),项目主持人
10)国家重大专项“中国海及邻域地质地球物理及地球化学系列图”,专题:中国西部主要块体构造纲要研究(GZH200900504,2009-2014),课题负责人
11)国家留学基金,反射地震资料揭示的青藏高原西北缘形变模式研究(2006331),项目主持人
12)国际合作项目(美国家自然科学基金项目),Lithosphere Structure across the Altun Range(NSF-EAR-9706338 and 9996212,1997-2001),中方负责人
13)国际合作项目(美国国家航空和宇宙航行局项目),Fracture Zone-Hot Spot Interactions along Northern Margin of Tibet(NASA NAG5-8456,1998-2002),中方负责人

主要学术领域

· 学科方向

构造地质与地球物理,海洋地球物理学

· 研究方向

岩石圈动力演化海洋油气地球物理勘探

· 近期研究兴趣

(1)南海西北部盆地构造沉积特征对青藏高原隆升的响应:研究青藏高原隆升挤出在中国近海盆地引起的构造沉积活动,揭示南海盆地成盆动力机制和演化模式;
(2)基于流体地球物理表征的新几内亚-所罗门弧俯冲起始动力学机制:揭示新几内亚-所罗门弧多期次多类型俯冲起始的主控因素,回答洋-洋板块深部俯冲起始动力学机制问题;
(3)海上深层宽频三维地震高精度采集处理解释技术:海上地震宽频立体采集模式和海上深层地震资料宽频处理解释技术研发;
(4)声信号对极区冰层和海底的响应及其声学参数观测技术:北极声信号跨介质传播的顶底界面模型构建,极区声信号采集及数据图像处理技术研发;
(5)海洋地质地球物理调查资料处理技术:中国近海及其邻近海域重磁资料处理数据和融合处理技术研发。

主要论文和论著目录

· 论文收录情况

发表SCI、EI等期刊、会议论文100余篇。

· 代表性文章列举如下

1.Jiang, X. D., Li, Z.-X., Li, C. Y., Gong, W., 2019. A Gravity Study of the Longmenshan Fault Zone: New Insights Into the Nature and Evolution of the Fault Zone and Extrusion‐Style Growth of the Tibetan Plateau Since 40 Ma, Tectonics, 38, 176-189.
2.Jiang, X. D., Li, Z.-X., 2014. Seismic reflection data support episodic and simultaneous growth of the Tibetan Plateau since 25 Myr,Nature Communications, 5:5453 doi: 10.1038/ncomms6453.
3.Jiang, X. D., Li, Z.-X., Li, H. B., 2013. Uplift of the West Kunlun Range, northern Tibetan Plateau, dominated by brittle thickening of the upper crust, Geology, 41, 4, 439-442.
4.Jiang, X. D., 2014. Dynamic support of the Tien Shan lithosphere based on flexural and rheological modeling,Journal of Asian Earth Sciences, 93, 37-48.
5.Jin, Y., Wang, E., and Jiang, X. D., 2008. The dynamic support and decoupling process of the Tibetan lithosphere based on the integration of flexural modeling with other geological and geophysical studies, Geological Society of America, Special Paper, 444, 89-104, doi:10.1130/2008.2444(06).
6.Jiang, X. D., Jin, Y., 2005. Mapping the deep lithospheric structure beneath the eastern margin of the Tibetan Plateau from gravity anomalies, Journal of Geophysical Research, 109, B07407.
7.Jiang, X. D., Jin, Y., McNutt, M. K., 2004. Lithospheric deformation beneath the AltynTagh and West Kunlun faults from recent gravity surveys, Journal of Geophysical Research, 109, B05406.
8.Gong, W., Jiang, X. D., Xing, J. H., Xu, C., Xu, X. Y., 2019. Heterogeneous strain regime at the west of the Ogasawara Plateau in the Western Pacific Ocean from inversion of earthquake focal mechanisms, Journal of Asian Earth Sciences, 180, 103868.
9.Gong, W., Jiang, X. D., Zhou, H. T., Xing, J. H., Li, C. Y., Yang, K., 2018. Varied thermo-rheological structure, mechanical anisotropy and lithospheric deformation of the southeastern Tibetan Plateau, Journal of Asian Earth Sciences, 163, 108-130.
10.Li, C. Y., Jiang, X. D., Gong, W., Li, D. Y., Li, C. Y., 2018. Surface uplift of the Central Yunnan Plateau since the Pliocene, Geological Journal, 53, 1, 386-396.
11.Gong, W., Jiang, X. D., Guo, Y. F., Xing, J. H., Li, C. Y., Sun, Y., 2017. Strike-slip tectonics within the northernmost Philippine Sea plate in an arc-continent collisional setting, Journal of Asian Earth Sciences, 146, 265-278.
12.Xing, J. H., Jiang, X. D., Li, D. Y., 2016. Seismic study of the mud diapir structures in the Okinawa Trough, Geological Journal, 51, S1, 203-208.
13.Li, D. Y., Jiang, X. D., Xu, F., Liu, J. S., Hou, G. W., 2016. Geochemistry of the Paleocene Clastic Rocks in Lishui Sag, East China Sea Shelf Basin: Implications for Tectonic Background and Provenance, Acta Geologica Sinica, 90, 1, 166-181.
14.Gong, W., Xing, J. H., Jiang, X. D., 2018. Heterogeneous subduction structure within the Pacific plate beneath the Izu-Bonin arc, Journal of Geodynamics, 116, 1-12.
15.Li, D. Y., Dong, B. J., Jiang, X. D., Xing, J. H., 2016. Geochemical evidence for provenance and tectonic background from the Palaeogene sedimentary rocks of the East China Sea Shelf Basin, Geological Journal, 51, S1,209-228.
16.Jiang, X. D. and Jin, Y., 2012. The Rheological Structure of the East Tibetan Plateau, Geophysical Research Abstracts, Vol. 14, EGU2012-1728.
17.Jiang, X. D. and Jin, Y., 2012. The foreland basin geometry along Longmen Range from high resolution Gravity data and its tectonic implication, EOS, Trans. AGU, 93(51), Fall Meeting Suppl., abstract, T33E-2696.
18.Jiang, X. D.,2012. Tectonic evolution of the East China Sea shelf since Cretaceous, AOGS-AGU (WPGM), SE54-A002.
19.Jiang, X. D., Partitioning the uplifting mechanism of the Tibetan plateau from the east to the west, 16th SEISMIX International Symposium on Multi-scale Seismic Imaging of the Earth's crust and Upper Mantle, P21.
20.Jiang, X. D., Can the satellite gravity replace the gravity survey to delineate lithospheric structure? 26th General Assembly of the International Union of Geodesy and Geophysics (IUGG).
21.Zhang, H. X., He, B. S., Jiang, X. D., 2010. Hydrocarbon detection principle and its application based on Biot’sporoelastic theory, Second IITA International Conference on Geoscience and Remote Sensing.
22.Li, D. Y., Jiang, X. D., Dong, B. J., 2015. Seismic Velocity Prediction Based on Petrophysical model and Application in Tight Gas Reservoir of the Xihu Depression, East China Sea Shelf Basin, 3rd International Workshop on Rock Physics.
23.Gong, W., Jiang, X. D., 2015. Tectonic implications of the temperature-time path of the rocks in the central segment of the Red River shear zone, 3rd International Workshop on Rock Physics.
24.Jiang, X. D., 2004. Lithospheric deformation in Central Asia derived from gravity data, Ph.D. dissertation, University of Hamburg.
25.Jiang, X. D., McNutt, M. K., Jin, Y., Wong, H. K., Zhao, L. H., 2001. Mapping the upper mantle lithospheric structures of China with gravity data, EOS, Trans. AGU, 82(47), Fall Meeting Suppl., abstract, T12F-12.
26.Jiang, X. D., Jin, Y., 2000. A new model of lithospheric deformation beneath the Okinawa Trough from gravity data analysis, 2000 Western Pacific Geophysics Meeting, abstract, 83.
27.Jin, Y., Garzione, C., Jiang, X. D., 2002. Tectonic evolution in the North China Basin, EOS, Trans. AGU, 83(47), Fall Meeting Suppl., abstract,T52A-1180.
28.姜效典,李德勇,宫伟,秘从勇. 2014. 青藏高原东西向差异形变与隆升机制,地球物理学报,57, 12, 4016-4028, doi:10.6038/cjg20141214.
29.宫伟,姜效典. 2017. 哀牢山-红河断裂带哀牢山-大象山段渐新世-早中新世热史演化及成因,地球科学, 42,2, 223-239.
30.宫伟,李朝阳,姜效典. 2017. 青藏高原隆升与南海开启:南海西北部盆-山耦合体系,地学前缘, 24,4,268-283.
31.周海廷,姜效典,李德勇,邢军辉,宫伟. 2017. 东海陆架盆地西湖凹陷岩石圈热流变性质,大地构造与成矿学,41, 3, 481-490.
32.程永寿,姜效典,张富元. 2015. 西太平洋拉蒙特平顶海山富钴结壳矿区圈定与资源量估算, 海洋学报,37, 1, 106-114.
33.王燚, 姜效典. 2014. 地球重力场球冠谐模型的分层构造和分析, 大地测量与地球动力学, 34, 5, 30-39.
34.李德勇, 张金亮, 姜效典, 江志强. 2013. 高邮凹陷南坡真武-曹庄地区戴南组砂岩成岩作用及其对储层性质的影响, 地球科学—中国地质大学学报, 38, 1, 130-142.
35.张会星, 何兵寿, 姜效典, 张锦昌. 2010.利用地震波在双相介质中的衰减特性检测油气, 石油地球物理勘探, 45, 3, 343-349.

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