Biography
Eralp’s research is on finite element modelling of single and polycrystals for accurate prediction of mechanical properties of critical applications. Eralp received his PhD from RWTH Aachen University and worked as a researcher at various places including Carnegie Mellon University Mechanical Eng. Dept., Max Planck Institute for Iron Research, Cornell University Mechanical & Aerospace Eng. Dept., Sabanci University, and University of Bristol Mechanical Eng. on different projects involving finite element modelling and crystal mechanics that were linked with manufacturing processes such as micro machining, welding and additive manufacturing. He is currently working on physics-based modelling of nuclear materials.
Most Recent Publications
Restraining geometrically-necessary dislocations to the active slip systems in a crystal plasticity-based finite element framework
Restraining geometrically-necessary dislocations to the active slip systems in a crystal plasticity-based finite element framework
Effect of grain boundary misorientation and carbide precipitation on damage initiation: a coupled crystal plasticity and phase field damage study
Effect of grain boundary misorientation and carbide precipitation on damage initiation: a coupled crystal plasticity and phase field damage study
Calibration and surrogate model-based sensitivity analysis of crystal plasticity finite element models
Calibration and surrogate model-based sensitivity analysis of crystal plasticity finite element models
A robust and efficient hybrid solver for crystal plasticity
A robust and efficient hybrid solver for crystal plasticity
Bridging Length Scales Efficiently Through Surrogate Modelling
Bridging Length Scales Efficiently Through Surrogate Modelling
Research Interests
- Crystal plasticity
- Finite element modeling
- Material characterization and modeling
Related Academics
Most Recent Publications
Restraining geometrically-necessary dislocations to the active slip systems in a crystal plasticity-based finite element framework
Restraining geometrically-necessary dislocations to the active slip systems in a crystal plasticity-based finite element framework
Effect of grain boundary misorientation and carbide precipitation on damage initiation: a coupled crystal plasticity and phase field damage study
Effect of grain boundary misorientation and carbide precipitation on damage initiation: a coupled crystal plasticity and phase field damage study
Calibration and surrogate model-based sensitivity analysis of crystal plasticity finite element models
Calibration and surrogate model-based sensitivity analysis of crystal plasticity finite element models
A robust and efficient hybrid solver for crystal plasticity
A robust and efficient hybrid solver for crystal plasticity
Bridging Length Scales Efficiently Through Surrogate Modelling
Bridging Length Scales Efficiently Through Surrogate Modelling
Most Recent Publications
Restraining geometrically-necessary dislocations to the active slip systems in a crystal plasticity-based finite element framework
Restraining geometrically-necessary dislocations to the active slip systems in a crystal plasticity-based finite element framework
Effect of grain boundary misorientation and carbide precipitation on damage initiation: a coupled crystal plasticity and phase field damage study
Effect of grain boundary misorientation and carbide precipitation on damage initiation: a coupled crystal plasticity and phase field damage study
Calibration and surrogate model-based sensitivity analysis of crystal plasticity finite element models
Calibration and surrogate model-based sensitivity analysis of crystal plasticity finite element models
A robust and efficient hybrid solver for crystal plasticity
A robust and efficient hybrid solver for crystal plasticity
Bridging Length Scales Efficiently Through Surrogate Modelling
Bridging Length Scales Efficiently Through Surrogate Modelling
