AbstractWe consider branching random walks in d-dimensional integer lattice with time–space i.i.d. offspring distributions. This model is known to exhibit a phase transition: If d≥3 and the environment is “not too random”, then, the total population grows as fast as its expectation with strictly positive probability. If, on the other hand, d≤2, or the environment is “random enough”, then the total population grows strictly slower than its expectation almost surely. We show the equivalence between the slow population growth and a natural localization property in terms of “replica overlap”. We also prove a certain stronger localization property, whenever the total population grows strictly slower than its expectation almost surely
We study branching random walks in random i.i.d. environment in $\Z^d, d \geq 1$. For this model, th...
Abstract. We study a spatial branching model, where the underlying motion is d-dimensional (d ≥ 1) B...
AbstractA discrete stochastic model is introduced for populations which are diffusing, interacting, ...
We consider branching random walks in d-dimensional integer lattice with time-space i.i.d. offspring...
We consider branching random walks in d-dimensional integer lattice with time-space i.i.d. offspring...
We consider a model of branching Brownian motions in random environment associated with the Poisson ...
We consider branching random walks in d-dimensional integer lattice with time–space i.i.d. offspring...
AbstractWe consider branching random walks in d-dimensional integer lattice with time–space i.i.d. o...
Recent investigations have demonstrated that continuous-time branching random walks on multidimensio...
We study the survival probability and the growth rate for branching random walks in random environme...
26 pages, 10 figuresInternational audienceWe study several lattice random walk models with stochasti...
We consider branching particle processes on discrete structures like the hypercube in a random fitne...
We consider a continuous time random walk X in random environment on Z+ such that its potential can ...
41p.We consider branching random walks on the Euclidean lattice in dimensions five and higher. In th...
Consider a critical nearest-neighbor branching random walk on the d-dimensional integer lattice init...
We study branching random walks in random i.i.d. environment in $\Z^d, d \geq 1$. For this model, th...
Abstract. We study a spatial branching model, where the underlying motion is d-dimensional (d ≥ 1) B...
AbstractA discrete stochastic model is introduced for populations which are diffusing, interacting, ...
We consider branching random walks in d-dimensional integer lattice with time-space i.i.d. offspring...
We consider branching random walks in d-dimensional integer lattice with time-space i.i.d. offspring...
We consider a model of branching Brownian motions in random environment associated with the Poisson ...
We consider branching random walks in d-dimensional integer lattice with time–space i.i.d. offspring...
AbstractWe consider branching random walks in d-dimensional integer lattice with time–space i.i.d. o...
Recent investigations have demonstrated that continuous-time branching random walks on multidimensio...
We study the survival probability and the growth rate for branching random walks in random environme...
26 pages, 10 figuresInternational audienceWe study several lattice random walk models with stochasti...
We consider branching particle processes on discrete structures like the hypercube in a random fitne...
We consider a continuous time random walk X in random environment on Z+ such that its potential can ...
41p.We consider branching random walks on the Euclidean lattice in dimensions five and higher. In th...
Consider a critical nearest-neighbor branching random walk on the d-dimensional integer lattice init...
We study branching random walks in random i.i.d. environment in $\Z^d, d \geq 1$. For this model, th...
Abstract. We study a spatial branching model, where the underlying motion is d-dimensional (d ≥ 1) B...
AbstractA discrete stochastic model is introduced for populations which are diffusing, interacting, ...