MODELING AND SIMULATION

FCRGroup Academics: R.Riahifar, M.S.Yaghmaee

                                                


Members

   Academics: M.S.Yaghmaee, R.Riahifar
   Researchers:
   M.Sc. Students:

   Honoree Members :


Modeling in Materials Sceince: PDF



 

Main goal: materials properties and phenomena (mostly at surface and atomistic level)

 

 


Method in modeling: mainly thermodynamics based (atomistic view)


Methods in Simulation: FEM, FDM, FVM, Monte Carlo, DEM, MD.


Research Directions: bulk properties, surface science, nano and inter-related fundamental experiments and develop engineering programs



Scales: macro- micro and nano-scale



Our Research team aims to model or simulate material science and engineering problems. In following there are some of our experiences on simulating and modeling:
 
 
 
1- Simulation of 3-d hot rolling of aluminum alloys (FEM-Abacus):
 

2- Simulation of resistance spot welding (FVM-Fortran code):

 
3- Simulation of final stage of sintering (Monte Carlo-Fortran code):
 

 

4- Simulation of slip casting (FDM-Fortran code):

5- Simulation of micro-cantilever (FEM-Ansys):

 

6- Simulation of particle agglomeration (DEM-Matlab code):

 

 

7- Thermodynamics Modeling and Mathematical Programming (Visual basic code) the Inner bond energy of Metals

 

 
Also, this is the list of other projects in our team:
 
8- Thermodynamics Modeling and Mathematical Programming (Visual basic code) the Surface Energy of Metals
9- Thermodynamics Modeling the Cohesion Energy of Nanostructure Materials
10- Thermodynamics Modeling and Mathematical Programming (Visual basic code) the Surface Melting Phenomena
11- Thermodynamics Modeling and Mathematical Programming (Visual basic code) the Melting Phenomena of NanoScale Materials (size, shape, crystallographic and surface planes effect)
12- Thermodynamics Modeling the atomic interaction in high temperature metallic melts
13-  Kinetics and Thermodynamics Modeling the formation (processing) criteria of composite materials
14- Thermodynamics Modeling the inner and surface Cohesion of Nano-Scale Materials
15- Kinetics and Thermodynamics Modeling the surface and chemical interaction in gaseous phase of plasma
16- Kinetics and Thermodynamics Modeling the surface and chemical interaction during the plasma deposition (gas-solid) processes