In this review paper, we introduce the recently developed Lattice Monte Carlo method for addressing and solving phenomenologically-based mass and heat transport problems especially for composite and porous materials. We describe in detail the application of this method to calculate effective mass diffusivities and to determine concentration profiles. Next, we describe in detail the application of this method to the calculation of effective thermal conductivities/thermal diffusivities and the determination of temperature profiles. Where possible, results of the method are compared with exact results or those from application of the Finite Element method. Excellent agreement is demonstrated
Lattice Monte Carlo methods are an excellent choice for the simulation of non-linear thermal diffusi...
This work addresses the effective thermal conductivity of cellular metals. Analytical relations for ...
Lattice Monte Carlo methods are an excellent choice for the simulation of non-linear thermal diffusi...
In this review paper, we introduce the recently developed Lattice Monte Carlo method for addressing...
In this overview, we introduce the recently developed Lattice Monte Carlo method for addressing and ...
In this paper, we review the recent developed method based around lattice-based random walks and the...
Ever since its development during World War II as part of the Manhattan Project, the Monte Carlo met...
The Lattice Monte Carlo (LMC) method recently developed by the authors is an unusually powerful and ...
This paper addresses the use of the Lattice Monte Carlo method for the thermal characterization of c...
This Chapter addresses the numerical simulation of thermal diffusion in multi-phase materials. A Lat...
In this paper, the Finite Element and lattice Monte Carlo methods are used to calculate the effectiv...
A correct strategy for evaluation of the effective thermal diffusivity, and, similarly, for the eval...
Heat conduction [1] is usually modeled as a diffusion process embodied in heat conduction equation. ...
The Lattice Monte Carlo method is a computationally intensive approach towards the study of thermal ...
International audienceFor simulating flows in a porous medium, a numerical tool based on the Lattice...
Lattice Monte Carlo methods are an excellent choice for the simulation of non-linear thermal diffusi...
This work addresses the effective thermal conductivity of cellular metals. Analytical relations for ...
Lattice Monte Carlo methods are an excellent choice for the simulation of non-linear thermal diffusi...
In this review paper, we introduce the recently developed Lattice Monte Carlo method for addressing...
In this overview, we introduce the recently developed Lattice Monte Carlo method for addressing and ...
In this paper, we review the recent developed method based around lattice-based random walks and the...
Ever since its development during World War II as part of the Manhattan Project, the Monte Carlo met...
The Lattice Monte Carlo (LMC) method recently developed by the authors is an unusually powerful and ...
This paper addresses the use of the Lattice Monte Carlo method for the thermal characterization of c...
This Chapter addresses the numerical simulation of thermal diffusion in multi-phase materials. A Lat...
In this paper, the Finite Element and lattice Monte Carlo methods are used to calculate the effectiv...
A correct strategy for evaluation of the effective thermal diffusivity, and, similarly, for the eval...
Heat conduction [1] is usually modeled as a diffusion process embodied in heat conduction equation. ...
The Lattice Monte Carlo method is a computationally intensive approach towards the study of thermal ...
International audienceFor simulating flows in a porous medium, a numerical tool based on the Lattice...
Lattice Monte Carlo methods are an excellent choice for the simulation of non-linear thermal diffusi...
This work addresses the effective thermal conductivity of cellular metals. Analytical relations for ...
Lattice Monte Carlo methods are an excellent choice for the simulation of non-linear thermal diffusi...