We consider hopping transport on an anisotropic two-dimensional square lattice. The displacements parallel to one axis are governed by uniform, nearest-neighbor hopping rates c, while the displacements parallel to the other axis are governed by static but spatially fluctuating rates wn. Adapting a new class of generating functions recently introduced for the random-trapping problem, we are able to obtain expressions for the mean-square displacement in the fluctuating direction through an exact decoupling of the effects due to displacements in the uniform direction. The resulting expressions for the low-frequency diffusion coefficient D(ε) are exact in the limits c →0 [D(0)=1/w-1] and c → ∞ [D(0)=〈w〉]. Moreover, when the condition of long-ti...
We introduce energy-projected equations of motion to treat the diffusive transport of charge carrier...
We describe an approach for computing the conductivity associated with long-range hopping on energet...
From a hopping rate equation for disordered materials we derive a macroscopic drift-diffusion equati...
We consider charge carriers that undergo nearest-neighbor hopping among the sites of a binary random...
International audienceWe consider a random-hopping model on a regular lattice. We describe a method ...
A study is made of the dynamical behavior of an electron or exciton undergoing anisotropic hopping o...
A microscopic transport theory is developed for stochastic and correlated hopping on ordered and ran...
The random walk numerical simulation (RWNS) method is used to compute diffusion coefficients for ho...
The recent work of Odagaki and Lax on the ac hopping conductivity in a one-dimensional bond-percolat...
The theory of electron transport via hopping between localised states is developed within the framew...
The low-field mobility μ of a small concentration of charge carriers hopping among a random distribu...
In the study of transport properties of randomly layered media, we use the recursive Green's functio...
The configurational average response of discrete one-dimensional disordered systems modeled by the c...
By a mean field aproximation a macroscopic charge transport equation is derived from a hopping model...
The velocity and the diffusion coefficient of a particle on a periodic one-dimensional lattice of pe...
We introduce energy-projected equations of motion to treat the diffusive transport of charge carrier...
We describe an approach for computing the conductivity associated with long-range hopping on energet...
From a hopping rate equation for disordered materials we derive a macroscopic drift-diffusion equati...
We consider charge carriers that undergo nearest-neighbor hopping among the sites of a binary random...
International audienceWe consider a random-hopping model on a regular lattice. We describe a method ...
A study is made of the dynamical behavior of an electron or exciton undergoing anisotropic hopping o...
A microscopic transport theory is developed for stochastic and correlated hopping on ordered and ran...
The random walk numerical simulation (RWNS) method is used to compute diffusion coefficients for ho...
The recent work of Odagaki and Lax on the ac hopping conductivity in a one-dimensional bond-percolat...
The theory of electron transport via hopping between localised states is developed within the framew...
The low-field mobility μ of a small concentration of charge carriers hopping among a random distribu...
In the study of transport properties of randomly layered media, we use the recursive Green's functio...
The configurational average response of discrete one-dimensional disordered systems modeled by the c...
By a mean field aproximation a macroscopic charge transport equation is derived from a hopping model...
The velocity and the diffusion coefficient of a particle on a periodic one-dimensional lattice of pe...
We introduce energy-projected equations of motion to treat the diffusive transport of charge carrier...
We describe an approach for computing the conductivity associated with long-range hopping on energet...
From a hopping rate equation for disordered materials we derive a macroscopic drift-diffusion equati...