In the present Short Note an idea is proposed to explain the emergence and the observation of processes in complex media that are driven by fractional non-Markovian master equations. Particle trajectories are assumed to be solely Markovian and described by the Continuous Time Random Walk model. But, as a consequence of the complexity of the medium, each trajectory is supposed to scale in time according to a particular random timescale. The link from this framework to microscopic dynamics is discussed and the distribution of timescales is computed. In particular, when a stationary distribution is considered, the timescale distribution is uniquely determined as a function related to the fundamental solution of the space-time fractional diffus...
International audienceWe analyze generalized space-time fractional motions on undirected networks an...
We study complex processes whose evolution in time rests on the occurrence of a large and random num...
The temporal Fokker–Planck equation (Boon et al. in J Stat Phys 3/4: 527, 2003) or propagation–dispe...
In the present Short Note an idea is proposed to explain the emergence and the observation of proces...
Kinetic equations describe the limiting deterministic evolution of properly scaled systems of intera...
AbstractTo offer an insight into the rapidly developing theory of fractional diffusion processes, we...
To offer an insight into the rapidly developing theory of fractional diffusion processes we describ...
We present a modelling approach for diffusion in a complex medium characterized by a random lengthsc...
In this chapter, we consider a randomly-scaled Gaussian process and discuss a number of applications...
In this contribution we show that fractional diffusion emerges from a simple Markovian Gaussian rand...
article in press: T.M. Michelitsch and A.P. Riascos, Continuous time random walk and diffusion with ...
A complex fractional derivative can be derived by formally extending the integer k in the kth deriva...
A physical-mathematical approach to anomalous diffusion may be based on generalized diffusion equati...
none2This book contains 20 contributions by the leading authors in fracrional dynmics. It covers t...
Functional limit theorems for continuous-time random walks (CTRW) are found in the general case of d...
International audienceWe analyze generalized space-time fractional motions on undirected networks an...
We study complex processes whose evolution in time rests on the occurrence of a large and random num...
The temporal Fokker–Planck equation (Boon et al. in J Stat Phys 3/4: 527, 2003) or propagation–dispe...
In the present Short Note an idea is proposed to explain the emergence and the observation of proces...
Kinetic equations describe the limiting deterministic evolution of properly scaled systems of intera...
AbstractTo offer an insight into the rapidly developing theory of fractional diffusion processes, we...
To offer an insight into the rapidly developing theory of fractional diffusion processes we describ...
We present a modelling approach for diffusion in a complex medium characterized by a random lengthsc...
In this chapter, we consider a randomly-scaled Gaussian process and discuss a number of applications...
In this contribution we show that fractional diffusion emerges from a simple Markovian Gaussian rand...
article in press: T.M. Michelitsch and A.P. Riascos, Continuous time random walk and diffusion with ...
A complex fractional derivative can be derived by formally extending the integer k in the kth deriva...
A physical-mathematical approach to anomalous diffusion may be based on generalized diffusion equati...
none2This book contains 20 contributions by the leading authors in fracrional dynmics. It covers t...
Functional limit theorems for continuous-time random walks (CTRW) are found in the general case of d...
International audienceWe analyze generalized space-time fractional motions on undirected networks an...
We study complex processes whose evolution in time rests on the occurrence of a large and random num...
The temporal Fokker–Planck equation (Boon et al. in J Stat Phys 3/4: 527, 2003) or propagation–dispe...