AbstractWe do the numerical analysis and simulations for the time fractional radial diffusion equation used to describe the anomalous subdiffusive transport processes on the symmetric diffusive field. Based on rewriting the equation in a new form, we first present two kinds of implicit finite difference schemes for numerically solving the equation. Then we strictly establish the stability and convergence results. We prove that the two schemes are both unconditionally stable and second order convergent with respect to the maximum norm. Some numerical results are presented to confirm the rates of convergence and the robustness of the numerical schemes. Finally, we do the physical simulations. Some interesting physical phenomena are revealed; ...
AbstractIn this paper, we consider the Lévy–Feller fractional diffusion equation, which is obtained ...
AbstractThis paper makes an attempt to develop a fractal derivative model of anomalous diffusion. We...
Summary This paper establishes a difference approximation on time-space fractional advectiondispersi...
AbstractWe do the numerical analysis and simulations for the time fractional radial diffusion equati...
Fractional analog of the reaction diffusion equation is used to model the subdiffusion process. Diff...
AbstractFractional diffusion equations replace the integer-order derivatives in space and time by th...
AbstractTo offer an insight into the rapidly developing theory of fractional diffusion processes, we...
In this paper, we consider a modified anomalous subdiffusion equation with a nonlinear source term f...
AbstractIn this paper, we study the time–space fractional order (fractional for simplicity) nonlinea...
Fractional Fokker–Planck equations have been used to model several physical situations that present ...
In this paper, a fractional partial differential equation (FPDE) describing sub-diffusion is conside...
In this paper we are concerned with the numerical solution of a diffusion equation in which the time...
Abstract There are a number of physical situations that can be modeled by fractional partial differe...
A physical-mathematical approach to anomalous diffusion may be based on generalized diffusion equati...
AbstractThis study makes the first attempt to apply the Kansa method in the solution of the time fra...
AbstractIn this paper, we consider the Lévy–Feller fractional diffusion equation, which is obtained ...
AbstractThis paper makes an attempt to develop a fractal derivative model of anomalous diffusion. We...
Summary This paper establishes a difference approximation on time-space fractional advectiondispersi...
AbstractWe do the numerical analysis and simulations for the time fractional radial diffusion equati...
Fractional analog of the reaction diffusion equation is used to model the subdiffusion process. Diff...
AbstractFractional diffusion equations replace the integer-order derivatives in space and time by th...
AbstractTo offer an insight into the rapidly developing theory of fractional diffusion processes, we...
In this paper, we consider a modified anomalous subdiffusion equation with a nonlinear source term f...
AbstractIn this paper, we study the time–space fractional order (fractional for simplicity) nonlinea...
Fractional Fokker–Planck equations have been used to model several physical situations that present ...
In this paper, a fractional partial differential equation (FPDE) describing sub-diffusion is conside...
In this paper we are concerned with the numerical solution of a diffusion equation in which the time...
Abstract There are a number of physical situations that can be modeled by fractional partial differe...
A physical-mathematical approach to anomalous diffusion may be based on generalized diffusion equati...
AbstractThis study makes the first attempt to apply the Kansa method in the solution of the time fra...
AbstractIn this paper, we consider the Lévy–Feller fractional diffusion equation, which is obtained ...
AbstractThis paper makes an attempt to develop a fractal derivative model of anomalous diffusion. We...
Summary This paper establishes a difference approximation on time-space fractional advectiondispersi...