彭翀

博士

通讯方式:chong.peng@seu.edu.cn, 17726625624

研究方向:

(1) 地质灾害(滑坡、泥石流)

(2) 计算力学和新型数值计算方法

(3) 光滑粒子流体动力学(SPH)

(4) 高性能计算

(5) 数值仿真技术在工程和工业中的应用

(6) 工业涂装技术

办公地点:土木工程学院705

 

 

个人简介

东南大学研究员,博士生导师。2007、2013年毕业于清华大学水利水电工程系,获学士、博士学位。2013-2015于英国诺丁汉大学和奥地利维也纳农业大学任玛丽-居里博士后,后任奥地利Engineering Software Steyr GmbH部门经理、首席技术官,2024年底入职东南大大学桥隧与地下工程系。


主持国家高层次人才项目(2022)、欧盟CELTIC-NEXT,HORIZON 2020、奥地利科学促进会(FFG)及国家自然科学基金项目,发表学术论文100余篇,总引用2000余次,多篇入选高被引论文。主要研究方向为新型数值计算方法,高性能计算,以及数值仿真在地质灾害和工业制造领域的应用,领衔开发的数值方法与软件被知名厂商如奥迪、宝马、大众、通用等公司采用。


每年招收博士生2名,硕士生2名。欢迎对数值计算方向感兴趣的同学加入团队。


科研、教改项目

代表性科研项目:

2023.01-2025.12 奥地利科学促进机构(FFG),“QuantumReady: Exploring the advantages of quantum computing for early adopters”,课题负责人

2022.03-2026.08 欧盟Celtic-Next,“COA-CFD: Cloud-based Online Access to Computational Fluid Dynamic Simulations”,项目负责人

2018.03-2021.02 奥地利科学促进机构(FFG),“SENSE: Affordable complex physics CFD simulation software for SMEs”,课题负责人

2018.01-2020.12 欧盟Horizon 2020,“Affordable CFD simulation software for SMEs in the transportation industry”,课题负责人

2018.01-2020.12 国家自然科学基金青年项目,“考虑运动全过程的泥石流亚塑性本构建模及其数值实现”,项目负责人


论文和专著

发表成果详见https://scholar.google.com/citations?user=v7832XYAAAAJ&hl=en&oi=sra


期刊论文

J69.

Chen JY, Song XZ*, Peng   C*. A coupled FD-SPH framework for the damage evaluation of ceramic-steel   composite structures subjected to blast loading. Computers and Structures,   309, 107653, 2025. DOI: 10.1016/j.compstruc.2025.107653.

J68.

Bi ZH, Wu W, Zhang LJ, Peng   C*. Efficient Random Field Generation with Rotational Anisotropy for   Probabilistic SPH Analysis of Slope Failure. International Journal for   Numerical and Analytical Methods in Geomechanics, 2024. DOI: 10.1002/nag.3858.

J67.

Basic M*, Blagojevic B,   Klarin B, Peng C, Basic J. Lagrangian Split-Step Method for   Viscoelastic Flows. Polymers, 16, 2068, 2024. DOI: 10.3390/polym16142068.

J66.

Chen JY, Feng DL*, Peng   C*, Ni RC, Wu YX, Li T, Song XZ. A   coupled FD-SPH method for shock-structure interaction and dynamic fracture   propagation modeling. Applied Mathematical Modelling, 134, 288-306,   2024. DOI: 10.1016/j.apm.2024.06.010.

J65.

Bi ZH, Wu W, Zhang LJ, Peng   C*. Uncertainty Analysis of Post-Failure Behavior in Landslides Based on   SPH Method and Generalized Geotechnical Random Field Theory. Computers and   Geotechnics, 171, 106363, 2024. DOI: 10.1016/j.compgeo.2024.

106363.

J64.

Paneer M, Bašić J*,   Sedlar D, Lozina Ž, Degiuli N, Peng C. Fluid Structure Interaction   Using Modal Superposition and Lagrangian CFD. Journal of Marine Science   and Engineering, 12(2), 318, 2024. DOI: 10.3390/jmse12020318

J63.

Zhu CW, Wu W, Peng C, Wang S*, Wei X. SPH implementation of a   critical state-based hypoplastic model for granular materials in   large-deformation problems. Computers and Geotechnics, 166, 106011,   2024. DOI: 10.1016/j.compgeo.2023.106011.

J62.

Zhou MJ, Shi ZM, Peng   C, Peng M*, Cui KFE, Li B, Zhang L, Zhou GGD. Two-phase modelling of   erosion and deposition process during overtopping failure of landslide dams   using GPU-accelerated ED-SPH. Computers and Geotechnics, 166, 105944,   2024. DOI: 10.1016/j.compgeo.2023.105944.

J61.

Zhu CW, Peng C, Wu   W*. Smoothed particle hydrodynamics modelling of particle-size segregation in   granular flows. Journal of Fluid Mechanics, 977, A47, 2023. DOI: 10.1017/   jfm.2023.995

J60.

Islam MRI*, Peng C,   Patra PK. A comparison of numerical stability for ESPH and TLSPH for dynamic   brittle fracture. Theoretical and Applied Fracture Mechanics, 127,   104052, 2023. DOI: 10.1016/j.tafmec.2023.104052.

J59.

Wang YD, Wu W, Peng C*.   Regularized SPH model for soil–structure interaction with generalized   frictional boundary. International Journal for Numerical and Analytical   Methods in Geomechanics, 47(10), 1852-1875, 2023. DOI: 10.1002/nag.3541.

J58.

Zhang W, Wu ZZ, Peng C,   Li S, Dong YK, Yuan WH*. Modelling large-scale landslide using a   GPU-accelerated 3D MPM with an efficient terrain contact algorithm. Computers   and Geotechnics, 158, 105411, 2023. DOI: 10.1016/j.compgeo.2023.105411.

J57.

Chen JY, Feng DL*, Sun QY, Peng C, Zhu YH, Yu SY. Numerical   modeling of shaped charge jet penetration into ceramic–metal double-layered   medium using smoothed particle hydrodynamics. International Journal of   Impact Engineering, 175, 104526, 2023. DOI:   10.1016/j.ijimpeng.2023.104526

J56.

Li S*, Tang H, Peng C, Turowski J, Schoepa   A, An H, Chen XQ, Ouyang CJ, Chen JG. Sensitivity and Calibration of ThreeDimensional SPH   Formulations in LargeScale   Landslide Modeling. Journal of Geophysical Research: Solid Earth, 128,   e2022JB024583, 2023. DOI: 10.1029/2022JB024583

J55.

Zhu CW, Peng C,   Wu W*. Lagrangian meshfree particle method (SPH) based simulation for   granular flow in a rotating drum with regularized μ(I) elastoplastic model. Powder   Technology, 408, 117699, 2022. DOI: 10.1016/j.powtec.2022.117699

J54.

Zhu CW, Peng C*,   Wu W, Wang C. A multi-layer SPH method for generic water–soil dynamic coupling   problems. Part I: Revisit, theory, and validation. Computer Methods in   Applied Mechanics and Engineering, 396, p.115106, 2022. DOI: 10.1016/j.cma.2022.115106.

J53.

Zhou MZ, Fang Q, Peng C*. A mortar segment-to-segment contact method   for stabilized total-Lagrangian smoothed particle hydrodynamics. Applied   Mathematical Modelling, 107, 20-38, 2022. DOI: 10.1016/j.apm.2022.02.022.

J52.

Liu SJ, Wang YT*, Peng   C, Wu, W. A thermodynamically consistent phase field model for mixed-mode   fracture in rock-like materials. Computer Methods in Applied Mechanics and   Engineering, 392, 114642, 2022. DOI: 10.1016/j.cma.2022.114642.

J51.

Peng C, Li   S, Wu W*, An HC, Chen XQ, Ouyang CJ, Tang H. On three-dimensional SPH   modelling of large-scale landslides. Canadian Geotechnical Journal,   59(1), 24-39, 2022. DOI: 10.1139/cgj-2020-0774.

J50.

Islam MRI, Zhang W, Peng   C*. Large deformation analysis of geomaterials using stabilized total   Lagrangian smoothed particle hydrodynamics. Engineering Analysis with   Boundary Elements, 136, 252-265. 2022. DOI:   10.1016/j.enganabound.2022.01.002.

J49.

Bašić M*, Blagojević B, Peng C, Bašić, J. Lagrangian   Differencing Dynamics for Time-Independent Non-Newtonian Materials. Materials,   14(20), 6210, 2021. DOI: 10.3390/ma1420.

J48.

Chen JY, Feng DL*, Wang   GY, Gao F, Peng C. Numerical Simulation of Detonation and Brisance   Performance of Aluminized HMX Using DensityAdaptive   SPH. Propellants, Explosives, Pyrotechnics, 46(12), 1800-1814, 2021.   DOI: 10.1002/prep.202100214.

J47.

Chen JY, Feng DL, Lien FS, Yee E, Deng SX, Gao F, Peng C*. Numerical modelling of interaction between   aluminium structure and explosion in soil. Applied Mathematical Modelling,   99, 760-784, 2021. DOI: 10.1016/j.apm.2021.07.010.

J46.

Peng C,   Bašić M, Blagojević B, Bašić J, Wu W*. A Lagrangian differencing dynamics   method for granular flow modeling. Computers and Geotechnics, 137,   104297, 2021. DOI: 10.1016/j. compgeo.2021.104297.

J45.

Wang C*, Ye GL, Meng XN, Wang YQ, Peng C. A Eulerian–Lagrangian   Coupled Method for the Simulation of Submerged Granular Column Collapse. Journal   of Marine Science and Engineering, 9(6), 617, 2021. DOI: 10.3390/jmse9060617.

J44.

Peng C*,   Zhan L, Wu W, Zhang BY. A fully resolved SPH-DEM method for heterogeneous   suspensions with arbitrary particle shape. Powder Technology, 387,   509-526, 2021. DOI: 10. 1016/j.powtec.2021.04.044.

J43.

Zhu C, Peng C, Wu W*. Applications of micropolar SPH in geomechanics. Acta Geotechnica,   16(8), 2355-2369, 2021. DOI: 10.1007/s11440-021-01177-x.

J42.

Zhang W, Zhong ZH, Peng   C, Yuan WH, Wu W*. GPU-accelerated smoothed particle finite element   method for large deformation analysis in geomechanics. Computers and   Geotechnics, 129, 2021, DOI: 0.1016/j.compgeo.2020.103856.

J41.

Chen JY, Feng DL, Deng SX, Peng C*, Lien FS. GPU-accelerated smoothed particle   hydrodynamics modeling of jet formation and penetration capability of shaped   charges. Journal of Fluids and Structures, 99, 2020, DOI:   10.1016/j.jfluidstructs. 2020.103171

J40.

Zhan L, Peng C*,   Zhang BY, Wu W. A surface mesh represented discrete element method (SMR-DEM)   for particles of arbitrary shape. Powder Technology, 2020, DOI:   j.powtec.2020.09.046.

J39.

Guo XG, Peng C, Wu W*, Wang YQ. Unified constitutive model for   granular-fluid mixture in quasi-static and dense flow regimes. Acta   Geotechnica, 2020, DOI: 10.1007/s11440-020-01044-1

J38.

Islam MRI, Bansal A, Peng   C*. Numerical simulation of metal machining process with Eulerian and   total-Lagrnagian SPH. Engineering Analysis with Boundary Elements,117,   269-283, 2020.

J37.

Li S, Peng C, Wu W*, Wang S, Chen XQ, Zhou GD, Chitneedi BK.   Role of baffle shape on debris flow impact in step-pools channel: an SPH   study. Landslides, 2020, in press.

J36.

Zhan L, Peng C*,   Zhang BY, Wu W. A SPH framework for dynamic interaction between soil and   rigid body system with hybrid contact method. International Journal for   Numerical and Analytical Methods in Geomechanics. DOI: 10.1002/nag.3070,   2020.

J35.

Chen JY, Lien FS, Peng C*, Yee E. GPU-accelerated smoothed   particle hydrodynamics modeling of granular flow. Powder Technology,   359, 94-106, 2020.

J34.

Zhou MZ, Zhang BY, Chen   TL, Peng C*, Fang HC. A three-field dual mortar method for elastic   problems with nonconforming mesh. Computer Methods in Applied Mechanics   and Engineering, 362, 112870, 2020.

J33.

Verma K*, McCabe C, Peng C, Wille R. A PCISPH implementation   using distributed multi-GPU acceleration for simulating industrial   engineering applications. The International Journal for High Performance   Computing Applications, 1094342020906199, 2020.

J32.

Cabrera MA*, Leonardi A, Peng   C. Granular flow simulation in a centrifugal acceleration field. Géotechnique.   DOI: 10.1680/jgeot.18.P.260, 2020.

J31.

Filho CADF*, Peng C, Islam MRI, McCabe C, Baig C, Prasad GKD.   Implementation of three-dimensional physical reflective boundary conditions   in mesh-free particle methods for continuum fluid dynamics: Validation tests   and case studies. Physics of Fluids, 31, 103605, 2019.

J30.

Peng C*,   Wang S, Wu W, Yu HS, Wang C, Chen JY. LOQUAT: an open-source GPU-accelerated   SPH solver for geotechnical modeling. Acta Geotechnica, 14(5),   1269-1287, 2019.

J29.

Zhan L, Peng C*, Zhang BY, Wu W. Three-dimensional modeling of   granular flow impact on rigid and deformable structures with a stabilized   TL-WC SPH method. Computers and Geotechnics, 112, 257-271, 2019.

J28.

Zhan L, Peng C*,   Zhang BY, Wu W. A stabilized TL-WC SPH approach with GPU acceleration for   three-dimensional fluid-structure interaction. Journal of Fluids and   Structures, 86, 329-353, 2019.

J27.

Yuan QQ, Wang C*, Wang YQ, Peng C, Meng XN. Investigation of submerged soil excavation   by high-velocity water jet using two-fluid smoothed particle hydrodynamics   method. Journal of Hydraulic Engineering, 145(6), 04019016, 2019.

J26.

Chen JY, Peng C*,   Lien FS, Yee E, Zhao XH. Simulations for the   explosion in a water-filled tube including cavitation using the SPH method. Computational   Particle Mechanics, 6(4), 515-527, 2019.

J25.

Islam MRI, Peng C*. A Total Lagrangian SPH method for modelling   damage and failure in solids. International Journal of Mechanical Sciences, 157, 498-511, 2019.

J24.

Peng C*,   Bauinger C, Szewc K, Wu W, Cao H. An improved predictive-corrective   incompressible smoothed particle hydrodynamics method for fluid flow   modeling. Journal of Hydrodynamics, 31(4), 654-668, 2019.

J23.

Wang W, Zhou MZ*, Peng C, Zhang BY. A dual mortar contact   method for porous media and its application to clay-core rockfill dams. International   Journal for Numerical and Analytical Methods in Geomechanics, 43(9),   1744-1769, 2019.

J22.

Chen JY*, Peng C,   Lien FS. Simulations for three-dimensional landmine detonation using the SPH   method. International Journal of Impact Engineering, 126, 40-49, 2019.

J21.

Wang S, Wu W*, Yin ZY, Peng C, He XZ. Modelling the   time-dependent behaviour of granular material with hypoplasticity. International Journal for Numerical and   Analytical Methods in Geomechanics, 42(12), 1331-1345, 2018.

J20.

Wang S, Wu W*, Peng C,   He XZ, Shan CD. Numerical integration and FE implementation of a hypoplastic   constitutive model. Acta Geotechnica, 13(6), 1265-1281, 2018.

J19.

Zhou MZ, Zhang BY, Peng C*. Numerical evaluation of soft   inter-slab joint in concrete-faced rockfill dam with dual mortar finite   element method. International Journal for Numerical and Analytical Methods   in Geomechanics, 42(5), 781-805, 2018.

J18.

Zhang BY, Chen T, Peng   C*, Qian XX, Jie YX. Experimental study on loading-creep coupling effect   in rockfill material. ASCE International Journal of Geomechanics,   17(9), 04017059, 2017.

J17.

Wang C*, Wang YQ, Peng C, Meng XN. Dilatancy and compaction effects on the   submerged granular column collapse. Phyiscs of Fluids, 29(10), 2017.

J16.

Xu GF*, Peng C, Wu W, Qi JL. A   combined constitutive model for the creep and steady flow rate of frozen soil   in unconfined condition. Canadian Geotechnical   Journal, 54(7), 907-914, 2017.

J15.

Wang C*, Wang YQ, Peng C, Meng XN. Two-fluid smoothed particle hydrodynamics simulation of submerged   granular column collapse. Mechanics Research Communications, 79,   15-23, 2017.

J14.

Peng C*,   Xu GF, Wu W, Yu HS, Wang C. Multiphase SPH modelling of free surface flow in   porous media with variable porosity. Computer and Geotechnics, 81,   239-248, 2017.

J13.

Peng C, Guo   XG, Wu W*, Wang YQ. Unified modelling of granular media with Smoothed   particle hydrodynamics. Acta Geotechnica, 11(6), 1231-1247, 2016.

J12.

Guo XG, Peng C, Wu   W*, Wang YQ. A hypoplastic constitutive model for debris materials. Acta   Geotechnica, 11(6), 1217-1229, 2016.

J11.

Zhou MZ, Zhang BY, Peng C*, Wu W. Three-dimensional numerical   analysis of concrete-faced rockfill dam using dual mortar finite element   method with mixed tangential contact formulation. International Journal   for Numerical and Analytical Methods in Geomechanics, 83(11), 1428-1465   2016.

J10.

Wang C*, Wang YQ, Peng   C, Meng XN. Smoothed Particle Hydrodynamics simulation   of water-soil mixture flows. ASCE Journal of Hydraulic Engineering,   142(11), 2016.

J9.

Peng C*, Wu   W, Yu HS, Wang C. A SPH approach for large deformation analysis with   hypoplastic constitutive model. Acta Geotechnica, 10(6): 703-717,   2015.

J8.

Peng C*,   Wu W, Zhang BY. Three-dimensional simulations of tensile cracks in   geomaterials by coupling meshless and finite element method. International   Journal for Numerical and Analytical Methods in Geomechanics, 39(2):   135-154, 2015.

J7.

Yuan HN*, Peng C, Lin Q, Zhang BY. Simulation of tensile   cracking in earth structures with an adaptive RPIM-FEM coupled method. KSCE   Journal of Civil Engineering, 18(7): 2007-2018, 2014.

J6.

Peng C*,   Yuan HY, Zhang BY, Zhang Y. Factors affecting accuracy of radial point   interpolation meshfree method for 3-D solid mechanics. Journal of Central   South University, 20: 3229-3246, 2013.

J5.

Peng C*, Wu   W. Modelling tensile cracking in compacted clay with meshless method. Beton-und   Stahlbetonbau, SI: 190-195, 2013.

J4.

彭翀*, 张宗亮, 张丙印,   袁友仁.   高土石坝裂缝分析的变形倾度有限元法及其应用.   岩土力学,   34(5), 1453-1458, 2013.

J3.

彭翀*, 袁会娜, 张丙印. 无网格自动加密方法及其在土体裂缝分析中的应用. 工程力学, 30(6), 231-235, 2013.

J2.

张琰*,   彭翀,   李星.   三维径向点插值无网格法及其在流固耦合中的应用.   岩土力学,   32(6), 1898-1904, 2011.

J1.

牛起飞, 侯瑜京*, 梁建辉, 彭翀. 坝肩变坡引起心墙裂缝和水力劈裂的离心模型试验研究, 32(12), 1935-1941, 2011.


荣誉和奖励

2022 - 国家高层次青年人才

2015 - 中国职业安全健康协会科学技术一等奖

指导学生

2名博士研究生获国家奖学金

1名博士研究生获清华大学优秀毕业生、北京市优秀毕业生


招收地质灾害模拟、无网格法、计算力学、计算流体力学等方向的硕士、博士研究生,数理、力学或编程能力优秀者优先。长期招募计算力学和地质灾害模拟方向博士后。