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中国海洋大学海洋地球科学学院导师教师师资介绍简介-邢会林(教授)

本站小编 Free考研考试/2020-11-27


一、基本信息
姓名:邢会林
性别:男
出生年月:1965年9月
祖籍:山东省博兴
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-
E-mail地址:h.xing@ouc.edu.cn
二、简历
1. 学习经历
哈尔滨工业大学,锻压 工学学士学位,中国哈尔滨,1989.07
哈尔滨工业大学,材料工程 工学硕士学位,中国哈尔滨,1992.03
哈尔滨工业大学,材料科学与工程/算工程科学 博士学位,中国哈尔滨,1995.03
日本理化学研究所(RIKEN) 计算工程科学 博士后, 日本和光,1995.11-1997.11
2. 工作经历
1995.03 哈尔滨工业大学 讲师
1997.11 – 2002.01 日本理化研究所(RIKEN)/地球模拟器 研究员
2002.02 - 2004.08 澳大利亚昆士兰大学地学计算中心 研究员
2002.07 - 2007.07 澳大利亚计算地球系统科学(ACcESS)国家研究设施地壳动力学负责人
2004.09 - 2010.05 澳大利亚昆士兰大学地学计算中心 高级研究员/博士生导师
2007.08 – 2015.7 澳大利亚国家基础设施AuScope (NCRIS)地壳动力学模拟负责人
2010.06 – 2018.10 澳大利亚昆士兰大学地学计算中心 主任研究员/博士生导师
2018.10 – 中国海洋大学 教授/博士生导师
3. 现今学术兼职
亚太地震仿真国际合作组织(ACES)国际科学委员会成员,澳方负责人
澳洲研究委员会(ARC-Australian Research Council)项目评阅人 (DP, LP, DECRE, Fellowship, LEIF 等)
中南大学、成都理工大学荣誉教授; 北京交通大学兼职教授
TAML(理论和应用力学快报)编辑委员会创刊成员(创刊至今)
国际期刊Petroleum编辑委员会创刊成员(创刊至今)
中南大学、成都理工大学荣誉教授
北京交通大学兼职教授
4. 国家科研项目
1) 国家自然科学基金联合基金项目,U**,阿尔金断裂东段大地震复发模型及其 力学机理研究,2019.01-2022.12,230万元,在研,参加
2) ARC(AustraliaResearchCouncil)DiscoveryProject, Mudstones as methanesources: as methanesources:gasproductionfromcoalseaminterburden,2015.01-2017.12 ,31.7万澳元,已结题,主持之一
3) 印度地质条件下的边墙开采设计和规范,澳大利亚-印度政府国际合作项目 (2014-2016), 2.6万澳元,已结题, 子项目负责人
4) 华北克拉通北缘铀多金属矿化流体动力学数值模拟,中核集团北京核地院国际合作项目,2015-2016,$65,000,已结题,主持
5) 国家自然科学基金面上项目,**,石英脉型黑钨矿床五层楼垂直形态分带 形成的动力学机制,2014.01-2017.12,90万元,已结题,参加
6) 国家自然科学基金重点项目,**,含液含液多孔介质力学分析的多层级建模 与计算方法研究,2013.01-2017.12,300万元,已结题,参加
7) Queensland Government Smart Futures Research Partnerships Program, Future gas through bioconversion of stranded and waste coal,2012.01-2015.12,85万 澳元,已结题,参加
8) Australian National Low Emissions Coal Research and Development (ANLEC), Achieving Risk and Cost Reductions in CO2 Geosequestration through 4D Characterisation of Host Formations,2011.01-2015.12,80万澳元,已结题,参加
9) ARC (Australia Research Council) Discovery Project,Multiscale and Multiphase Modeling of Deformable Porous Media,2010.01-2013.12, 44万澳元, 已结题, 主持之一
10) ARC Linkage International,Supercomputer Simulation of Multiscale Dynamic Behaviour in Multiphase Deformable Porous Media,2009.01-2010.12,10.7万澳元,已结题,主持
11) 国家自然科学基金海外青年****合作研究基金(2007年度),**,地球动力学,2008.01-2010.12,40万元,已结题,主持
12) Australian Commonwealth Government ,NCRIS Funding scheme,QLD Node Simu lation & Modelling of AuScope Structure and Evolution of the Australian Continent,2007.01-2011.12,4.8百万澳元,已结题,主持之一
13) Australian Commonwealth Government, Queensland State government,ESyS_Crustal (project 4.5),2007.01-2011.12,352,740 澳元,已结题,主持
14) ARC Discovery Project. Supercomputer Simulation and Risk Evaluation of Tsunami Generation Induced by Earthquakes,2006.01-2008.12,27.5万澳元,已结题 ,主持
15) ARC Linkage project with Geodynamics Ltd,Supercomputer Simulation of H ot Fractured Rock Geothermal Reservoir Systems,2005.01-2008.12,45万澳元,已结题,主持
16) Australia Commonwealth Government, ACcESS MNRF (Australian Computa tional Earth Science Simulator, Major National Research Facility),2002.01-2007 .12,1480万澳元,已结题,主持之一
17) ARC Spirt Project with Main Road Department,C**,Numerical Simul ation of Seismic Activity ,2002.01-2005.12,37.5万澳元,已结题,参加
18) Japan STA,Earth Simulator Project,1997.01-2001.12,40000万美元,已结题,参加
19) Sheet Forming Simulation Research Group (including Toyota, Nissan, IBM Japan etc 31 companies), Japan,Finite Element Modeling of Sheet Metal Forming Processes,1995.01-2002.12,100万美元,已结题,参加
20) STA Japan,CROSSOVER Project-Simulation Techniques for Multiscale Pheno mena in Nuclear Power Plants,1995.01-2000.12,60万美元已结题,参加
三、主要学术领域
1.学科方向:
超级计算地球科学及其地质、资源及灾害等领域的应用
2. 应用研究
结合地球数字化发展趋势,将数值模拟、超级计算与固体地球科学、地质、资源及灾害等领域的应用相结合,长期从事相关非线性多尺度多相多场耦合计算理论(有限元及LBM),程序开发及相关的应用工作。所研发的软件PANDAS已应用于地壳动力学,地震,海啸,滑坡,数字岩心及非常规油气储层增渗改造(如水力压裂、酸化驱、生物驱、冲击波驱等),地下库区多尺度描述、多场耦合分析及评估等(如干热岩发电、非常规油气增渗开采、微生物产气、深部工程开挖、CO2埋藏、金属钨及铀矿成矿机理及预测等)。
3. 近期研究兴趣
将围绕固体地球科学、工程、资源、灾害及环境等问题,利用超级计算、现代观测及地球大数据等先进科技,在已有PANDAS软件平台基础上,开展多尺度多相多场耦合超级地学计算理论、软件及应用研究。将来尤其是在海底科学与工程方面,以应对人类在“深海进入、深海探测、深海开发” 的深海认知过程中所面临的巨大科技挑战,搭建国际合作与交流的平台,建立国内一流、国际知名的海底科学与工程仿真团队/实验室。
充分利用现代高性能计算、大数据和可视化方法及工具:
(1) 在海底地球科学及灾害领域,结合空-天-地-海一体化多源立体观测或历史数据记录,加深对海底动力过程演化和机理的理解,以期实现对自然和人类活动诱发的重大地质灾害及环境潜在隐患进行早期评估、识别甚至预警。
(2) 在资源开发工程领域,实现比目前更深更复杂的非常规环境下更有效、更绿色的勘探及可持续安全开采。将来重点是海洋深部/非常规的地球工程(即海底矿床/盆地特征、工程设计、开采及相关地质环境灾害评价与防治);
(3) 在计算地球科学与工程领域,实现基于大数据的内部特征信息提取、自适应网格化生成、模拟仿真计算、3D可视化、3D打印及验证等一体化;
(4) 与世界先进的国际大学在海洋计算地学及其工程应用的科研、复合型高层次人才培育及技术转移等方面建立紧密合作关系。
四、主要论文和论著目录
代表性文章列表如下:
论著共180 余篇,主要的文章清单如下。其中,*是指导的学生为第一作者,#是指导的年轻博士后或访问****为第一作者。未有特殊标记的本人第一作者论文,同时也是通讯作者。

Scholarly Books

1. Xing, Huilinand Xu, Xiwei. M8.0 Wenchuan Earthquake, 2011, 191 p., Hardcover. Springer-Verlag Berlin Heidelbergm. ISBN 978-3-642-01875-6.
2. Xing, Huilin, Advances in Geocomputing. Springer-Verlag Berlin Heidelbergm, 2009, 325 p. 124 illus. with DVD., Hardcover, ISBN: 978-3-540-85877-5
3. Xing, H. Land Wang, J. H (Ed). Geodynamic Modeling, A Special Issue of Acta Geotechnica, Number 2, 2009. Springer Berlin/Heidelbergm(for the selected papers presented in IACGG2007 - International Workshop on Advances in Computational Geomechanics and Geophysics).
书中的章节ScholarlyBook Chapters:

4. Xing, H. L., Yu, W and Zhang, J (2009), 3D mesh generation in geocomputing, Chapter II in Advances in Geocomputing, Springer-Verlag GmbH, pp27-64. DOI: 10.1007/978-3-540-85879-9_2.
5. *Liu, Y., Y. Shi, E. O. D. Sevre, H L Xingand D. A Yuen (2009). Probabilistic Forecast of Tsunami Hazards along ChineseCoast, Chapter VIII in Advance in Geo-Computing, Springer-Verlag GmbH, pp279-317, DOI:10.1007/978-3-540-85879-9_8.
6. Xing, H.L.,& Makinouchi, A. (2000), Thermo-elasto-plastic FE modelling of heat exchanger assembling process. In Supercomputing in Nuclear Applications (Yagawa, G., eds), Tokyo, RE032, 1-20

期刊论文Referred Journal Articles
7. #Liu, Xiangchong, Ma, Yue, Xing, Huilin and Zhang, Dehui (2018) Chemical responses to hydraulic fracturing and wolframite precipitation in the vein-type tungsten deposits of southern China. Ore Geology Reviews, 102 44-58. doi:10.1016/j.oregeorev.2018.08.027
8. *Yi, Jie and Xing, Huilin (2018) Finite element lattice Boltzmann method for fluid flow through complex fractured media with permeable matrix. Advances in Water Resources, 119 28-40. doi:10.1016/j.advwatres.2018.06.007
9. *Gao, Mei-Ben, Li, Tian-Bin, Meng, Lu-Bo, Ma, Chun-Chi and Xing, Hui-lin (2018) Identifying crack initiation stress threshold in brittle rocks using axial strain stiffness characteristics. Journal of Mountain Science, 15 6: 1371-1382. doi:10.1007/s11629-018-4847-z
10. #Yao, Qi, Xu, XiWei, Xing, HuiLin, Cheng, Jia, Jiang, GuoYan, Ma, WeiYu, Liu, Jie and Yang, Wen (2018) 3D seismogenic model of the 2015 Gorkha earthquake and subsequent seismic risk. Chinese Journal of Geophysics-Chinese Edition, 61 6: 2332-2343. doi:10.6038/cjg2018L0371
11. *Ren, Fei, Ge, Lei, Rufford, Thomas E., Xing, Huilin and Rudolph, Victor (2018) Permeability enhancement of coal by chemical-free fracturing using high-voltage electrohydraulic discharge. Journal of Natural Gas Science and Engineering, 57 1-10. doi:10.1016/j.jngse.2018.06.034
12. #Liu, Xiangchong, Xing, Huilin and Zhang, Dehui (2018) Hydraulic fracturing leads to wolframite deposition at magmatic-hydrothermal transition. Acta Geologica Sinica - English Edition, 92 2: 862-863. doi:10.1111/1755-6724.13562
13. #Yao, Qi, Xing, Hui-Lin, Xu, Xi-Wei, Zhang, Wei and Liu, Jie (2018) Simulation of Seismic Risk in the Daliangshan Sub-Block and Adjacent Areas Using the Nonlinear Friction FEM Method 利用非线性摩擦有限元方法计算大凉山次级块体及其周边地区地震危险性. Dizhen Dizhi, 40 1: 171-185. doi:10.3969/j.issn.0253-4967.2018.01.013
14. *Jiang, Yupeng and Xing, Huilin (2018) Theoretical research of pressure propagation in pulsating hydraulic fracturing for coal permeability enhancement. International Journal of Oil Gas and Coal Technology, 17 1: 91-112. doi:10.1504/IJOGCT.2018.**
15. #Chen, Fangwen, Lu, Shuangfang, Ding, Xue, He, Xipeng and Xing, Huilin (2018) The splicing of backscattered scanning electron microscopy method used on evaluation of microscopic pore characteristics in shale sample and compared with results from other methods. Journal of Petroleum Science and Engineering, 160 207-218. doi:10.1016/j.petrol.2017.10.063
16. #Xiangchong Liu, Huilin Xing, Dehui Zhang (2017). The mechanisms and time scale of alteration halos in vein-type tungsten deposits in southern China. Ore Geology Reviews. 89, 1019-1029. DOI:10.1016/j.oregeorev.2017.07.024
17. #Fangwen Chen, Xue Ding, Shuangfang Lu, Xipeng He & Huilin Xing (2017). Gas generation characteristics of the lower cambrian niutitang shale in qiannan depression, China. Petroleum Science and Technology, 35:12, 1209-1216, DOI: 10.1080/**.2017.**
18. #Fangwen Chen, Shuangfang Lu, Xue Ding, Xipeng He & Huilin Xing (2017). Evaluation of the Adsorbed Gas Amount in a Shale Reservoir Using the Three Compositions Adsorbing Methane (TCAM) Method: A Case from the Longmaxi Shale in Southeast Chongqing, China. Energy and Fuels (accepted). DOI: 10.1021/acs.energyfuels.7b01088
19. #Fangwen Chen, Shuangfang Lu, Xue Ding, Xipeng He & Huilin Xing. The splicing of backscattered scanning electron microscopy method used on evaluation of microscopic pore characteristics in shale sample and compared with results from other methods. Journal of Petroleum Science and Engineering 160 (2018) 207–218
20. * Gao J, Xing H, Turner L, Steel K, Sedek M, Golding SD, Rudolph V(2017). Pore-scale numerical investigation on chemical stimulation in coal and permeability enhancement for coal seam gas production. Transport in Porous Media. 1-17, doi:10.1007/s11242-016-0777-9
21. #Xiangchong Liu, Huilin Xing, Dehui Zhang (2017). Influences of Hydraulic Fracturing on Fluid Flow and Mineralization at the Vein-Type Tungsten Deposits in Southern China. Geofluids, Volume 2017 (2017), Article ID **, 11 pages. DOI:10.1155/2017/**
22. *Chunchi Ma, Yupeng Jiang, Huilin Xing and Tianbin Li (2017). Numerical modelling of fracturing effect stimulated by pulsating hydraulic fracturing in coal seam gas reservoir. Journal of Natural Gas Science and Engineering, DOI: 10.1016/j.jngse.2017.08.016
23. *J Gao, H Xing, Z Tian, JK Pearce, M Sedek, SD Golding, V Rudolph.(2017). Reactive transport in porous media for CO 2 sequestration: Pore scale modeling using the lattice Boltzmann method. Computers & Geosciences 98, 9-20
24. *Jie Yi and Huilin Xing (2017). Pore-scale simulation of effects of coal wettability on bubble-water flow in coal cleats using Lattice Boltzmann Method. Chemical Engineering Science, 161,57-66. DOI: 10.1016/j.ces.2016.12.016 (corresponding author)
25. *Yupeng Jiang, Huilin Xing (2017). Theoretical research of pressure propagation in pulsating hydraulic fracturing for coal permeability enhancement, International Journal of Oil, Gas and Coal Technology (accepted) (corresponding author)
26. *Liu Yan and Huilin Xing (2016). An effective 3D meshing approach for fractured rocks, Int. J. Numer. Meth. Engng, 107:363–376. DOI: 10.1002/nme.5166 (corresponding author)
27. *Li Quanshu, Huilin Xing (2016). Influences of the Intersection Angle between Interlayer and In situ Stresses during Hydraulic Fracturing Process, Journal of Natural Gas Science & Engineering 36: 963-985
28. *Yupeng Jiang, Huilin Xing (2016). Numerical modelling of acoustic stimulation induced mechanical vibration enhancing coal permeability. Journal of Natural Gas Science and Engineering, 36, Part A, 786–799. DOI:10.1016/j.jngse.2016.11.008 (corresponding author)
29. *Li Qin and Huilin Xing (2016). A new method for determining the equivalent permeability of a cleat dominated coal sample. Journal of Natural Gas Science and Engineering. 34: 280–290 (corresponding author)
30. *X Liu, H Xing, D Zhang (2016). Influences of fluid properties on the hydrothermal fluid flow and alteration halos at the Dajishan tungsten deposit, China. Journal of Geochemical ExplorationJournal of Geochemical Exploration. 163: 53–69
31. *Li, Quanshu, Xing, Huilin (2016). Numerical analysis of the material parameter effects on the initiation of hydraulic fracture in a near wellbore region. Journal of Natural Gas Science and Engineering, 27:1597-1608. DOI: 10.1016/j.jngse.2015.10.023.
32. *Ma CC, Li TB, Xing HL, Zhang H, Wang MJ, Liu TY, Chen GQ, Chen ZQ (2016). Brittle Rock Modeling Approach and its Validation Using Excavation-Induced Micro-Seismicity. Rock Mechanics and Rock Engineering, 1-14. doi:10.1007/s00603-016-0941-0
33. #Tian, Zhiwei, Xing, Huilin, Tan, Yunliang, Gu, Sai and Golding, Suzanne D. (2016) Reactive transport LBM model for CO2 injection in fractured reservoirs. Computers and Geosciences, 86 15-22. doi:10.1016/j.cageo.2015.10.002
34. #Chen, Shaojie, Wang, Hailong, Zhang, Junwen, Xing, Huilin and Wang, Huaiyuan (2015) Low-strength similar materials for backfill mining: insight from experiments on components and influence mechanism. Geotechnical Testing Journal, 38 6: 1-7. doi:10.1520/GTJ**
35. *Guo, Ting-ting, Xu, Xi-wei, Xing, Hui-lin and Yu, Gui-hua (2015). Nonlinear finite-element simulation of conjugate faults system and associated earthquake swarm. Seismicity Geology, 37 2: 598-612. doi:10.3969/j.issn.0253-4967.2015.02.021
36. *X Liu, H Xing, D Zhang (2015). The mechanisms of the infill textures and its implications for the five-floor zonation at the Dajishan vein-type tungsten deposit, China. Ore Geology Reviews 65, 365-374 (corresponding author)
37. *Li, Quanshu, Xing, Huilin, Liu, Jianjun and Liu, Xiangchon (2015) A review on hydraulic fracturing of unconventional reservoir. Petroleum, 1 1: 8-15. doi:10.1016/j.petlm.2015.03.008
38. Xing Huilin, Liu, Yan, Gao, Jinfang and Chen, Shaojie (2015) Recent development in numerical simulation of enhanced geothermal reservoirs. Journal of Earth Science, 26 1: 28-36. doi:10.1007/s12583-015-0506-2
39. #Chen Shaojie, Wang, Hailong, Zhang, Junwen, Xing, Huilin and Wang, Huaiyuan (2015) Experimental study on low-strength similar-material proportioning and properties for coal mining. Advances in Materials Science and Engineering, 696501.1-696501.6. doi:10.1155/2015/696501
40. *Gao Jinfang, Xing Huilin, Rudolph, Victor, Li, Qin and Golding, Sue D. (2015) Parallel lattice Boltzmann computing and applications in core sample feature evaluation. Transport in Porous Media, 107 1: 65-77. doi:10.1007/s11242-014-0425-1
41. HL Xing, RW Ding, DA Yuen (2015). Tsunami hazards along the Eastern Australian Coast from potential earthquakes: results from numerical simulations. Pure and Applied Geophysics 172 (8), 2087-2115
42. #Zhiwei Tian, Huilin Xing, Yunliang Tan and Jinfang Gao (2014). A Coupled Lattice Boltzmann Model for Simulating Geochemical Reaction Transport in CO2 Injection. Physica A: Statistical Mechanics and its Applications 403, 155-164, (corresponding author)
43. Xing, Huilin (2014). Numerical simulation of transient geothermal flow in extremely heterogeneous fractured porous media, Journal of Geochemical Exploration 144, 168-178.
44. *Liu X, H Xing, D Zhang (2014). Fluid focusing and its link to vertical morphological zonation at the Dajishan vein-type tungsten deposit, South China. Ore Geology Reviews. 62, 245-258, 2014 (corresponding author)
45. H Xing, Y Liu (2014). Mesh Generation for 3D Geological Reservoirs with Arbitrary Stratigraphic Surface Constraints. Procedia Computer Science 29, 897-909.
46. *Liu Yan and Xing, Huilin (2014). A feature extracting and meshing approach for sheet-like structures in rocks. Computer Methods in Applied Mechanics and Engineering, 276, 396-409 (corresponding author)
47. *Gao J, Xing H, Tian Z and H Muhlhaus (2014). Lattice Boltzmann modeling and evaluation of fluid flow in heterogeneous porous media involving multiple matrix constituents, Computers and Geosciences, 62, 198–207 (corresponding author).
48. #Yao Qi, Xu Xiwei, Xing Huilin, Xu Chongand Wang Xiaohui(2013) Decomposition and evolution of intracontinental strike-slip faults in Eastern Tibetan Plateau. Acta Geologica Sinica-English Edition, 87 2: 304-317.
49. *Liu Y and H. L. Xing (2013). Surface mesh generation of large-scale digital rock images in 3D. Procedia Computer Science 18, 1208–1216. DOI: 10.1016/j.procs.2013.05.287(9 pages)
50. *Gao J, Xing H (2013). Scale Effect of 3D Heterogeneous Porous Media on Geo-Fluid Characteristics: Insight from Massively Parallel Lattice Boltzmann Computing . SPE SPE-167043-MS.
51. *Liu Y and Xing HL (2013). A boundary focused quadrilateral mesh generation algorithm for multi-material structures, Journal of Computational Physics, 232 (1) 516–528. doi:10.1016/j.jcp.2012.08.042 (corresponding author)
52. HW Zhang, ZQ Xie, BS Chen, HL Xing (2012), A finite element model for 2D elastic–plastic contact analysis of multiple Cosserat materials, European Journal of Mechanics-A/Solids 31 (1), 139-151. doi:10.1016/j.euromechsol.2011.07.005
53. #Yao Qi, Xu Xiwei, Xing Huilin, Zhang Wei, Gao Xiang (2012), Deformation mechanism of the eastern Tibetan plateau: Insights from numerical models, Chinese Journal of Geophysics, 55 3: 863-874.
54. #Zheng-zhao Liang, H. L. Xing, D. J. Williams and Chun-an Tang (2012). Numerical investigation of fracture of rock specimen containing a pre-existing surface flaw, Computers & Geotechnics, 45, 19–33
55. *Gao, J and Xing H (2012). LBM simulation of fluid flow in fractured porous media with permeable matrix, Theor. Appl. Mech. Lett. Theor. Appl. Mech. Lett. 2, 032001 (2012) (corresponding author)
56. *Zhang J and H. Xing (2011), Numerical modeling of non-Darcy flow in near-well region of a geothermal reservoir, Geothermics, 42, 78–86. doi:10.1016/j.geothermics.2011.11.002
57. # Yao Qi,Xing Huilin,Xu Xiwei,Zhang Wei. (2012). Influence of lithologic differences on either walls of the fault on the Wenchuan earthquake. Chinese Journal of Geophysics, 55 11: 3634-3647.
58. H Xing, Y Liu (2011). Automated quadrilateral mesh generation for digital image structures, Theor. Appl. Mech. Lett. 1, 061001 (2011); doi:10.1063/2.**
59. *Liu, Y, H. L. Xing and Z Guan (2011). An indirect approach for automatic generation of quadrilateral meshes with arbitrary line constraints. Int J Num Methods Engng, 87, 906-922. DOI: 10.1002/nme.3145 (corresponding author)
60. *Zhang, S Q, Xing, H L, Yuen, D A, Zhang H and Shi Y (2011). Regional stress fields under Tibet from 3D global flow simulation, J Earth Sciences, 22, 155-159, DOI: 10.1007/s12583-011-0167-8.
61. Zhang, H.W., Q. Zhou, H.L. Xing, H. Muhlhaus (2010). A DEM study on the effective thermal conductivity of granular assemblies, Powder Technol., 205, 172-183 doi:10.1016/j.powtec.2010.09.008.
62. #Yuan, Ren-Mao, Xi-Wei Xu, Gui-Hua Chen, Xi-Bin Tan, Yann Klinger, and Hui-Lin Xing (2010). Ejection Landslide at Northern Terminus of Beichuan Rupture Triggered by the 2008 Mw 7.9 Wenchuan Earthquake, Bulletin of the Seismological Society of America, Vol. 100, 2689–2699, doi: 10.1785/.
63. Xing, H. L. and J. Zhang (2009). Finite Element Modeling of Non-linear Deformation Behaviours of Rate-Dependent Materials using an R-minimum Strategy, Acta Geotechnica, 4, 139-148. doi: 10.1007/s11440-009-0090-7.
64. *Liu, Y, Shi, Y ,. Yuen, D A, Sevre, E O. D., Yuan, X. and Xing H L(2009). Comparison of linear and nonlinear shallow wave water equations applied to tsunami waves over the China Sea. Acta Geotechnica. 4, 129-137. doi:10.1007/s11440-008-0073-0
65. #Liu, E and Xing, H. L. (2009). A Double Hardening Thermo-Mechanical Constitutive Model for Over Consolidated Clays, Acta Geotechnica, 4, 1-6, doi:10.1007/s11440-008-0053-4
66. Xing, H. L. and Wang, J (2009). Geodynamic Modeling, Acta Geotechnica (2009) 4:149. DOI 10.1007/s11440-009-0096-1
67. Xing, H., A. Makinouchiand C. Zhao (2008). Three-dimensional finite element simulation of large-scale nonlinear contact friction problems in deformable rocks, Journal of Geophysics and Engineering, 5, 27-36.
68. #Yin, C., Xing, H., Mora, P. and Xu, H (2008). Earthquake trend around Sumatraregion indicated by a new implementation of LURR method, Pure and Applied Geophysics, 165, 723–736, DOI 10.1007/s00024-008-0322-z
69. #Olsen-Kettle, L. M., D. Weatherley, E. Saez, L. Gross, H.-B. Mühlhaus, and H. L. Xing (2008), Analysis of slip-weakening frictional laws with static restrengthening and their implications on the scaling, asymmetry, and mode of dynamic rupture on homogeneous and bimaterial interfaces, J. Geophys. Res., 113, B08307, doi:10.1029/2007JB005454.
70. #Zhu, S B, Xing, H L, Xie, F R and Shi, Y L (2008). Simulation of earthquake processes by finite element method: The case of megathrust earthquakes on the Sumatrasubduction zone. Chinese Journal of Geophysics, 51, 460-468.
71. Xing, H. L., Makinouchi, A. and Mora, P. (2007). Finite element modeling of interacting fault system, Physics of the Earth and Planetary Interiors, 163, 106-121.doi:10.1016/j.pepi.2007.05.006
72. Xing, H. L. and Zhang, J. (2007). An R-minimum strategy for finite element modeling of non-linear deformation behaviours of rate-dependent materials, Lecture Notes in Computational Science (LNCS) 2007, 1093-1100, Springer-Verlag, Berlin, Heidelberg (sci).
73. #Xu, H, Xing, H. L., Wyborn, D and Mora, P (2007), Analytical and numerical investigation of thermo-fluid flow of fracture dominated geothermal reservoir, Lecture Notes in Computational Science (LNCS) 2007, 1156-1163
74. #Liu, E. L. and Xing, H. L. (2007). Modeling of the thermo-mechanical behavior of saturated soils, Lecture Notes in Computational Science (LNCS) 2007, 1151-1155
75. *Liu, Y., Shi, Y. Liu, H., Wang, S., Yuen, D and Xing, H. L.(2007). Can tsunami waves in the South China Sea be modelled with linear theory, Lecture Notes in Computational Science (LNCS) 2007, pp1205-1209
76. Yao, Y., Wang, N., Yamamoto, H and Xing, H. L. (2007), An elastoplastic model considering sand crushing, Lecture Notes in Computational Science (LNCS) 2007, pp1146-1150.
77. Xing, H. L., Zhang, J. and Yin, C. (2007). A finite element analysis of tidal deformation of the entire Earth with a discontinuous outer layer, Geophysical Journal International, 170 (3), 961–970. doi:10.1111/j.1365-246X.2007.03442.x
78. Xing, H. L., Mora, P., Makinouchi, A. (2006). An unified friction description and its application to simulation of frictional instability using finite element method. Philosophy Magazine. 86, 3453-3475
79. Xing, H. L., Mora, P. (2006). Construction of an intraplate fault system model of South Australia, and simulation tool for the iSERVO institute seed project. Pure and Applied Geophysics, 163, 2297-2316.
80. Gross, L., Mora, P., Saez, E., Weatherley, D. and Xing, H (2005). Software infrastructure for solving non-linear partial differential equations and its application to modeling crustal fault systems. ANZIAM J. 46(E) pp. C1141-1154
81. Mora, P., Muhlhaus, H., Gross, L., Xing, H., Weatherley, D., Abe, S., Latham, S., Moresi, L., (2005). ACcESS: Australia’s Contribution to the iSERVO Institute’s Development, Computing in Science & Engineering, 7(No.4) 27-37
82. Xing, H. L., Mora, P., & Makinouchi, A. (2004). Finite element analysis of fault bend influence on stick-slip instability along an intra-plate fault, Pure and Applied Geophysics, 161, 2091-2102
83. Xing, H.L., Zhang, K. F & Wang, Z. R. (2004). A perform design method for sheet superplastic bulging with finite element modeling, J. Mater. Proc. Tech., 151, 284-288
84. Xing, H.L., Zhang, K. F & Wang, Z. R. (2004). Recent development in the mechanics of superplasticity and its applications, J. Mater. Proc. Tech., 151, 196-202
85. Xing, H.L., & Makinouchi, A. (2003). Finite element modeling of frictional instability between deformable rocks. Inter. J. Numer. Anal. Meth. Geomech. 27, pp 1005-1025.
86. Xing, H L, Mora, P and Makinouchi, A. (2003) Finite element computing of stress evolution in a frictional contact system, Lecture Notes in Computer Science, 2659, pp.798-806.
87. Xing, H.L., Makinouchi, A. (2002), Finite-element modeling of multibody contact and its application to active faults. Concurrency and Computation: Practice and Experience, 14, pp 431-450.
88. Xing, H.L., & Makinouchi, A. (2002), Three dimensional finite element modeling of thermomechanical frictional contact between finite deformation bodies using R-minimum strategy, Computer Methods in Applied Mechanics and Engineering, 191, pp 4193-4214.
89. Xing, H.L., & Makinouchi, A. (2002), FE modelling of thermo-elasto-plastic finite deformation and its application in sheet warm forming, Engineering Computations – Int. J. Computer-Aided Engineering and Software, 19, pp 392-410.
90. Xing, H.L., & Makinouchi, A. (2002), Finite element analysis of sandwich friction experimental model of rocks, Pure and Applied Geophysics, 159, pp 1985-2009.
91. Xing, H.L., & Makinouchi, A. (2001), Numerical analysis and design for tubular hydroforming, Int. J. Mech. Sci., 43, pp 1009-1026.
92. Xing, H.L., & Makinouchi, A. (2000), A node-to-point contact element strategy and its applications, RIKEN Review: Focused on High Performance Computing, 30, pp 35-39.
93. Xing, H.L., Wang, S., & Makinouchi, A. (1999), An adaptive mesh h-refinement algorithm and its application to sheet forming, J. Mater. Process. Tech., 91, 813-190.
94. Xing, H.L., Wang, Z.R. (1998), Prediction and control of cavity growth during superplastic sheet forming with finite element modelling, J. Mater. Process. Tech., 75, pp 87-93.
95. Xing, H.L., Wang, Z.R. (1997), Finite element analysis and design of thin sheet superplastic forming, J. Mater. Process. Tech., 68, 1-7
96. Xing, H.L, Zhang, K.F., Qiao, Y. & Wang, Z.R.(1995). An advanced superplastic sheet-forming machine controlled by microcomputer, Journal of Materials Processing Technology, 55, 43-47
97. Xing, H.L., Wang, Z.R. (1994). The superplastic tensile instability, Chinese Science Bulletin(in English), 39, 23-26
98. Xing, H.L., Wang, Z.R.(1994). A study of the methods for measuring m and n values of superplastic materials, Journal of Materials Processing Technology, 41, 399-407
99. Xing, H.L., Zhang, K.F., Wang, Z.R.(1994). Study on the optimal mode of superplastic deformation, Journal of Materials Processing Technology, 44, 29-34
五、招生招聘
1. 每年招收相关学科硕士研究生2-3名,博士研究生2名,博士后1-3名,欢迎跨学科报考;对计算科学/力学、计算图形学及其在地学及工程领域应用感兴趣的优先录取。特别优秀的青年****,可申报学校和国家人才计划。
2. 研究生在读期间基本要求
a.在全国性学术会议做学术报告1次(硕士),加国际学术会议1次(博士或特别优秀的硕士)
b.硕士完成一篇SCI或两篇核心论文,博士完成2-3篇SCI论文
c. 具有正确的价值观,有团队协作精神。其他需满足学院和学校的基本要求。

相关话题/中国海洋大学 海洋