The paper addresses approximate integral-balance approach to a time-fractional diffusion equation of order 0 < μ < 1 with a time-dependent diffusion coefficient of power-law type D(t)=D0tβ where 0 < β < 1. The form of the solution spreading in a semi-infinite medium through an analysis of the second moment of the approximate solution reveals that depending on the sum μ+β the solution can model subdiffusive (μ+β<1), superdiffusive (μ+β>1) or Gaussian (μ+β=1) process of transport. The optimal exponents of the approximate parabolic profiles have been determined by minimization the mean squared error of approximation over the penetration depth
none2This book contains 20 contributions by the leading authors in fracrional dynmics. It covers t...
Fractional analog of the reaction diffusion equation is used to model the subdiffusion process. Diff...
AbstractIn this paper, we study the time–space fractional order (fractional for simplicity) nonlinea...
The work presents integral solutions of the fractional subdiffusion equation by an integral method, ...
This paper presents approximate analytical solutions of an initial-boundary value problem of frac...
An approximate analytical solution of transient diffusion equation with space-fractional Riemann–Lio...
AbstractThis paper presents an extension to the time integral characteristics method for estimation ...
Abstract We prove optimal estimates for the decay in time of solutions to a rather general class of...
Abstract The dissertation considers the time fractional diffusion equation (TFDE) with the Dirichlet...
A subdiffusion process, similar to a Zeldovich-Kompaneets heat conduction process, is defined by a n...
The work presents an integral solution of the time-fractional subdiffusion equation as alternative a...
AbstractThe fundamental solution of the fractional diffusion equation of distributed order in time (...
We prove optimal estimates for the decay in time of solutions to a rather general class of non-loca...
We focus on a subdiffusion–reaction system in which substances are separated at the initia...
This paper presents the alternative construction of the diffusion-advection equation in the range (1...
none2This book contains 20 contributions by the leading authors in fracrional dynmics. It covers t...
Fractional analog of the reaction diffusion equation is used to model the subdiffusion process. Diff...
AbstractIn this paper, we study the time–space fractional order (fractional for simplicity) nonlinea...
The work presents integral solutions of the fractional subdiffusion equation by an integral method, ...
This paper presents approximate analytical solutions of an initial-boundary value problem of frac...
An approximate analytical solution of transient diffusion equation with space-fractional Riemann–Lio...
AbstractThis paper presents an extension to the time integral characteristics method for estimation ...
Abstract We prove optimal estimates for the decay in time of solutions to a rather general class of...
Abstract The dissertation considers the time fractional diffusion equation (TFDE) with the Dirichlet...
A subdiffusion process, similar to a Zeldovich-Kompaneets heat conduction process, is defined by a n...
The work presents an integral solution of the time-fractional subdiffusion equation as alternative a...
AbstractThe fundamental solution of the fractional diffusion equation of distributed order in time (...
We prove optimal estimates for the decay in time of solutions to a rather general class of non-loca...
We focus on a subdiffusion–reaction system in which substances are separated at the initia...
This paper presents the alternative construction of the diffusion-advection equation in the range (1...
none2This book contains 20 contributions by the leading authors in fracrional dynmics. It covers t...
Fractional analog of the reaction diffusion equation is used to model the subdiffusion process. Diff...
AbstractIn this paper, we study the time–space fractional order (fractional for simplicity) nonlinea...