My research focuses on computational modeling of fluid–structure interaction and structural failure in ocean and marine environments. Using mesh-free methods such as Smoothed Particle Hydrodynamics (SPH), I study wave-structure interaction, hydrodynamic impact, and underwater blast loading on naval and offshore structures. A key goal is to understand structural damage, crack initiation, and dynamic failure under extreme marine conditions. My research also integrates high-performance computing and emerging data-driven approaches to develop predictive numerical tools that support safer and more resilient design of ships, offshore platforms, and coastal infrastructure.
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Three-dimensional SPH modeling of brittle fracture under hydrodynamic loading by Singh V., Peng C. , Ibne Islam M. R. Computers & Fluids 301 106763- (2025)
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On the Equivalence of Eulerian Smoothed Particle Hydrodynamics, Total Lagrangian Smoothed Particle Hydrodynamics and Molecular Dynamics Simulations for Solids by Ibne Islam M. R., Ganesh K. V., Patra P. K. Computer Methods in Applied Mechanics and Engineering 391 114591- (2022)
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A Total Lagrangian SPH Method for Modelling Damage and Failure in Solids by Ibne M. R., Peng C. International Journal of Mechanical Sciences 157-158 498-511 (2019)
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On Consistency and Energy Conservation in Smoothed Particle Hydrodynamics by Ibne Islam M. R., Chakraborty S. , Shaw A. International Journal for Numerical Methods in Engineering 116 601-632 (2018)
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Numerical Modelling of Crack Initiation, Propagation and Branching under Dynamic Loading by Ibne Islam M. R., Shaw A. Engineering Fracture Mechanics 224 106760- (2020)
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Implementation of Three-Dimensional Physical Reflective Boundary Conditions in Mesh-Free ParticleMethods for Continuum Fluid Dynamics: Validation Tests and Case Studies by Fraga Filho C. A., Peng C. , Ibne Islam M. R., Mccabe C. , Baig S. , Prasad G. V. Physics of Fluids 31 103606- (2019)
Principal Investigator
- Proof review (vetting) of prestressed concrete sleeper design referencing drawing No T-10280 CALCUTTA SPRINGS LIMITED
Co-Principal Investigator
- An SPH-based Parallel Solver (Software) for Simulating 2-D Mechanical Response under IMPact Load with Improved Accuracy and Time Complexity Directorate of Futuristic Technology Management (DFTM), Defence Research and Development Organisation, Ministry of Defence
Ph. D. Students
Abdulrehaman Asif Bagwan
Area of Research: Computational Mechanics
