Plenary Lecture
Directors
- Nguyen-Xuan Hung, Ho Chi Minh City University of Technology (HUTECH)
Open Submissions |
Peer Reviewed |
MS-000 General Papers
If you do not have a prefered MS or could not find a proper one at this moment, you may simply submit your abastract/paper here. The conference Chairmen will assign your submission to a MS or a Session for presentation later.
Directors
- Nguyen-Xuan Hung, Ho Chi Minh City University of Technology (HUTECH)
- GR Liu, ICCM Conference Chairman
Open Submissions |
Peer Reviewed |
MS-001 Theory and Formulation for Novel Computational Methods
Directors
- GR Liu, ICCM Conference Chairman
Open Submissions |
Peer Reviewed |
MS-002 Particle Based Methods
Directors
- Zhen Chen, University of Missouri
- Yan Liu, Tsinghua University
- Xiong Zhang, Tsinghua University
Open Submissions |
Peer Reviewed |
MS-003 Mechanics of surface/interface and bionics
Directors
- Shaohua Chen, Beijing Institute of Technology
Open Submissions |
Peer Reviewed |
MS-004 Boundary Element Methods and Mesh Reduction Methods
- Boundary Element Method
- Fundamental Solution and Trefftz Method
- Engineering Application of Boundary Element Method
- Coupling of Boundary Element Method with Other Methods
- Meshless and Particle Methods
- Material Point Method
- Coupling of Meshless and Particle Method with Other Methods
Directors
- Xiao-Wei Gao, Dalian University of Technology
Open Submissions |
Peer Reviewed |
MS-005 Reduced order models for structures and fluids
Directors
- Ke Liang, Northwestern Polytechnical University
- Jianyao Yao, Chongqing University
Open Submissions |
Peer Reviewed |
MS-006 Energy Absorption and crashworthiness of Structures and Materials
This MS is interested in all of the researches including energy absorption under static or dynamic loadings, crashworthiness, optimization and modelling. It also includes macro and micro scopes of structures and materials when talking about energy absorption and crashworthiness.
Directors
- Qinghua Qin, Xi'an Jiaotong University
- Xiong Zhang, Huazhong University of Science and Technology
Open Submissions |
Peer Reviewed |
MS-007 Fire Simulation
Directors
- Zhao Tian, University of Adelaide
Open Submissions |
Peer Reviewed |
MS-008 Modeling and Simulation of Complex Flow and Transport Phenomena
Directors
- Shuyu Sun, King Abdullah University of Science and Technology
- Bo Yu, Beijing Institute of Petrochemical Technology
Open Submissions |
Peer Reviewed |
MS-009 Computational Methods in Fluid Engineering
Directors
- Songying Chen, Shandong University
- Deyu Luan, Qingdao University of Science and Technology
Open Submissions |
Peer Reviewed |
MS-010 Data-driven Surrogate Modeling Techniques for Inverse and Other Related Problems
The surrogate modeling technique is an important tool for inverse problems. However, with the ever-increasing complexity of inverse problems, the surrogate modeling technique is difficult to handle some critical issues, such as curse of dimensionality, uncertainties, massive sampling data, etc. Therefore, in this minisymposium, some recently proposed novel strategies might be employed for inverse and other related problems. The themes involve but not limited to:
- Surrogate modeling theory and methodology;
- Surrogate-based optimization;
- Surrogate-assisted evolutionary optimization;
- Machine learning methods in surrogate modeling;
- Uncertainty Quantification and Propagation in Surrogate modeling;
- Data-driven (Numerical simulation-based) design and optimization ;
- Design of Experiments for surrogate modeling;
- Surrogate model assessment;
- Surrogate modeling for large data set and high dimensional problems;
- Surrogate modeling and surrogate-based optimization in practical engineering applications.
Directors
- Hu Wang, Hunan University
- Jian Zhang, Jiangsu University
Open Submissions |
Peer Reviewed |
MS-011 Damage and Failure Modelling in Composite Materials
Directors
Open Submissions |
Peer Reviewed |
MS-012 Deformation, Fatigue and Fracture of Advanced Materials
Directors
- Rong Jiang, Nanjing University of Aeronautics and Astronautics
- Liguo Zhao, Loughborough University
Open Submissions |
Peer Reviewed |
MS-013 Large Scale Coupled Problems and Related Topics
Directors
- Hiroshi Kanayama, Japan Women's University
- Lijun Liu, Osaka University
- Masao Ogino, Daido University
- Ryuji Shioya, Toyo University
Open Submissions |
Peer Reviewed |
MS-014 Progresses of Computational Marine Hydrodynamics
Directors
- Decheng Wan, Shanghai Jiao Tong University
- Aman Zhang, Harbin Engineering University
- Guiyong Zhang, Dalian University of Technology
Open Submissions |
Peer Reviewed |
MS-015 Smoothed Finite Element Methods and Related Techniques
Directors
- Yuki Onishi, Tokyo Institute of Technology
Open Submissions |
Peer Reviewed |
MS-016 Computational Mechanics for Composite Plates and Shells
Directors
- Tarun Kant, Indian Institute of Technology Bombay
Open Submissions |
Peer Reviewed |
MS-017 Computational methods in Hydraulic engineering
Directors
- Nguyen The Hung, The University of Danang
Open Submissions |
Peer Reviewed |
MS-018 Data, Uncertainty, Machine Learning and Digital Twin
- Data mining in engineering
- Statistical methods
- AI and machine learning methods for engineering computations
- Real time computing
- Digital twin
- Collocation methods
- Uncertainty quantification
- Mode order reduction
- Heterogeneous material modelling
- Structural reliability and risk assessment
- Other related subjects
Directors
- Chenfeng Li, Swansea University
Open Submissions |
Peer Reviewed |
MS-019 Methods for Multi-Phase Flows
Directors
- Dia Zeidan, German Jordanian University
- Lucy Zhang, Rensselaer Polytechnic Institute
Open Submissions |
Peer Reviewed |
MS-020 Particle-based methods and applications to geomechanics
Directors
- Ha BUI, Monash University
- Giang Nguyen, University of Adelaide
Open Submissions |
Peer Reviewed |
MS-021 Concurrent multiscale modeling from electrons to finite elements
The state-of-art super computers can explicitly deal with atoms in order of billions, which are about the atoms within one micron cube. It is unlikely in near future that the brutal force atomistic modeling can solve engineering material systems that involve physical phenomena across 10 orders of magnitude in length scale, such as fracture. Finite element modeling cannot reach the accuracy, but the atomistic modeling cannot fit the size requirements. Multiple length scale modeling is required to perform atomics (as well as quantum) simulations over macro scales. It requires the coupling between finite elements to the atoms and electrons side-by-side (hands-shaking). Such concurrent multi-length scalemodeling is very challenging. Talks are solicited for both the development of algorithms and applications of concurrent multi-length scale modeling in computational mechanics, such as Quasi-Continuum method, coupled atomistic and discrete dislocation method, concurrent atomistic-continuum method, multiscale coarse-graining method, super-atom method, dissipative particle dynamics, coarse-grained molecular dynamics, micromorphic theory, and atomistic field theory. This minisymposium is dedicated to concurrent multi-length scale modeling. Some of the topics of interest are:
Contributions that integrate experimental and computational approaches in mechanics and materials are particularly encouraged.
Directors
- Qiang Cao, Wuhan University
- Qing Peng, Institute of Mechanics, Chinese Academy of Sciences
Open Submissions |
Peer Reviewed |
MS-022 Multiscale modelling of engineering materials
Directors
- Sarah Zhang, Western Sydney University
Open Submissions |
Peer Reviewed |
MS-023 Advances in computational methods for large deformation problems in geo-mechanic
Directors
- Domenico Lombardi, The University of Manchester
Open Submissions |
Peer Reviewed |
MS-024 Recent Advances In Meshfree and Particle Methods
Directors
- Bin Chen, Xi'an Jiaotong University
Open Submissions |
Peer Reviewed |
MS-025 Meshfree and Other Advanced Numerical Methods for Engineering and Applied Mathematical Problems
The development of powerful meshfree and other advanced numerical methods for both routine and sophisticated engineering problems with complex solutions has been recognized by many researchers to benefit the industry as a whole, while creating new avenues for further research and spearheading of pioneering efforts within the field of computational and industrial applications. The objective of this minisymposium is to present the sate-of-the-art and prospective directions of those advanced numerical methods from the research areas to computation and application fields for engineering and applied mathematical problems.
Contributions are solicited in all subjects related to meshfree and other advanced numerical methods and their numerical applications, which include but are not limited to the following topics:
- Recent advances in meshfree methods, smoothed particle hydrodynamics, peridynamics, material point methods and other advanced numerical methods.
- Strong-form collocation meshfree methods and generalized finite difference methods.
- Applications of meshfree methods and other numerical methods for the numerical simulation of advanced materials and structures, soft materials, inverse problems, fluid dynamics and fluid-structure interaction, geomechanics, large deformation and non-linear problems, multi-phase interactions, contact and impact, static and dynamic structural responses, manufacturing processes, nano mechanics, etc.
Directors
- Lihua Wang, Tongji University
- Chuanzeng Zhang, Universitat Siegen
- Zheng Zhong, Harbin Institute of Technology
Open Submissions |
Peer Reviewed |
MS-026 Limit state analysis of structures and materials
Directors
- Canh Le, International University - VNU
Open Submissions |
Peer Reviewed |
MS-027 Modeling and Simulation for Additive Manufacturing
Additive manufacturing (AM), known as 3D printing, has attracted increasing interest from the community of researchers in the past decades, owing to the advances in printing materials and high-precision of printing technology that allow to fabricate organic and complex structures, which are challenging for traditional manufacturing methods. The difficulties surrounding the structural design for AM are hot topics, including residual stresses, undesirable microstructures, length scale control, as well as the challenge of computational costs for large scale structures. Modeling and simulation are a significant tool inherent in material and structure design for AM. The main objective of this mini-symposium is to provide a forum to discuss ongoing modeling and simulation techniques applied to AM. The presentations include (but not limit to):
- Simulation process to predict residual stresses/deformations and surface topology.
- Modelling of materials considering effects of printing direction related to microstructural anisotropy.
- Modeling and simulation of functionally graded materials, tissue engineering scaffolds, bioinspired composites, etc.
- Modeling of novel material systems.
- Multiscale topology optimization of lightweight materials for AM.
- Computational methods for material and structure design for AM.
- Topology optimization with structural feature control (length scale, multiple length scale, porosity,...) for AM
Directors
- Van-Nam Hoang, Vietnam Maritime University
- Nguyen-Xuan Hung, Ho Chi Minh City University of Technology (HUTECH)
- Jonathan Tran, RMIT University
Open Submissions |
Peer Reviewed |
MS-028 Computational Acoustics and Elastodynamics in Materials and Structures
The Mini-Symposium "Computational Acoustics and Elastodynamics in Materials and Structures" is aimed at gathering together the experienced researchers, postdoctoral fellows, and graduate students with backgrounds of different scientific disciplines to discuss and share the latest findings and development in computational methods and applications in the area of acoustics and elastodynamics in materials and structures. It will provide a superior platform for discussion and exploration of the possibilities enabled by various computational techniques for different research areas, including nondestructive testing, acoustics and underwater acoustics, material and mechanical engineering, aerospace, civil, medical ultrasound elastography, and many others. Contributions related to this subject area are warmly welcome.
Directors
- Weiqiu Chen, Zhejiang University
- Yue-Sheng Wang, Tianjin University/ Beijing Jiaotong University
- Bin Wu, Politecnico di Torino
- Chuanzeng Zhang, Universitat Siegen
Open Submissions |
Peer Reviewed |
MS-029 Kernel and machine learning based solutions of PDEs
Directors
- Elena Atroshchenko, The University of New South Wales
- Zhuojia Fu, Hohai University
- Timon Rabczuk, Bauhaus Universität Weimar
Germany
Open Submissions |
Peer Reviewed |
MS-030 New methods of approximate static calculations
The bearing systems of e.g. buildings due to application of appropriate complex methods of structural analyses are safe and constructed in an economic way. Comprehensive structural analyses are not necessary in each stage of the engineering design. In some cases application of methods of approximate static calculations are advised or required in order to get a reliable base for the preliminary considerations of numerous variants of possible technical solutions. Conclusions following from such considerations will indicate the most efficient way to obtain the bearing system having the assumed features. The Mini-Symposium is intended as a platform for presentation of such new methods of the approximate analyses.
Directors
- Janusz Rębielak, Cracow University of Technology
Open Submissions |
Peer Reviewed |
MS-031 Stochastic BEM in Fracture Mechanics
Various deterministic methods for analysis of engineering fracture problems have been well developed in the framework of the traditional theory of fracture mechanics. However, due to the inherent uncertainties in crack geometry, material properties and external loadings, deterministic analysis cannot provide a complete picture of reality for structures with cracks. Probabilistic fracture mechanics, which combines the classical theory of fracture mechanics with the probability theory, provides statistical characteristics of cracked structures with uncertain parameters. Owing to the unique advantage of BEM in the analysis of cracked structures, stochastic BEM has proved to be an effective approach to the probabilistic problems of fracture mechanics.
The goal of this mini-symposium is to bring together researchers working on BEM in probabilistic fracture mechanics. Potential topics may include, but are not limited to:
- Recent advances in probabilistic fracture mechanics
- Stochastic boundary element method
- Fracture reliability analysis of cracked structures with uncertainties
- Fatigue life prediction of cracked structures with uncertainties
- Random vibration analysis of cracked structures under stochastic loadings
- Engineering applications of probabilistic fracture mechanics
Directors
- Su Cheng, South China University of Technology
- Zhongwei Guan, University of Liverpool
Open Submissions |
Peer Reviewed |
MS-032 Acoustic metamaterials and phononic crystals: from fundamental theory to potential applications
Directors
- Feng Jin, Xi'an Jiaotong University
Open Submissions |
Peer Reviewed |
MS-033 Design optimization of structures and metamaterials
Directors
- Zhan Kang, Dalian University of Technology
Open Submissions |
Peer Reviewed |
MS-034 Local and nonlocal modeling approaches in dynamics
Directors
- Ugo Galvanetto, University of Padua
Italy
- Pawel Packo, AGH - University of Science and Technology
- Micro Zaccariotto, University of Padova
Open Submissions |
Peer Reviewed |
MS-035 Computational Biomechanics
Directors
- Ken-ichi Tsubota, Chiba University
- Gong Xiaobo, Shanghai Jiao Tong University
Open Submissions |
Peer Reviewed |
MS-036 Recent Advances and Developments for Damage and Failure of Engineering Materials and Structures
This mini-symposium aims at bringing together scientists and researchers working on the developments of formulation and/or numerical methods in computational fracture mechanics, including but not limited to the following research subjects:
- Phase Field Model and Variational Approaches to Fracture
- Local and Nonlocal Smeared Continuum Damage Models
- Extended and Generalized Finite Element Methods
- Peridynamics
- Strong Discontinuity Methods & Discontinuous Galerkin Methods
- Adaptive methods
- Meshfree methods: Material Point Methods, Reproducing Kernel Particle Methods, etc.
- Cohesive Fracture Models, Cohesive elements
- Impact Analysis
- Models for crack nucleation and evolution in materials with electric, magnetic, and chemical fields
- Transition from Damage to Fracture
- Quasi-brittle and ductile failure modeling
- Failure of composites and structures
Directors
- Tinh Quoc Bui, Tokyo Institute of Technology
Open Submissions |
Peer Reviewed |
MS-37 Modelling Heterogeneous Media: Fracture, Localisation and Multiphase Flow
Directors
- Daniel Dias da Costa, University of Sydney
- Yixiang Gan, University of Sydney
- Leong Hien Poh, National University of Singapore
- Luming Shen, The University of Sydney
Open Submissions |
Peer Reviewed |
Publication at eProceedings
Directors
- GR Liu, ICCM Conference Chairman
Open Submissions |
Peer Reviewed |
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