Consider stochastic heat equations with fractional Laplacian on R-d. The driving noise is generalized Gaussian which is white in time but spatially homogeneous. We study the large-scale structure of the tall peaks for (i) the linear stochastic heat equation and (ii) the parabolic Anderson model. We obtain the largest order of the peaks and compute the macroscopic Hausdorff dimensions of the peaks for (i) and (ii). These result imply that both (i) and (ii) exhibit multi-fractal behavior even though only (ii) is intermittent. This is an extension of a result of Khoshnevisan et al. (2017) to a wider class of stochastic heat equations. (C) 2018 Elsevier B.V. All rights reserved.11Nsciescopu
Cette thèse est consacrée à l'étude de certaines classes d'équations aux dérivées partielles stocha...
International audienceWe consider the stochastic heat equation with multiplicative noise $u_t=\frac{...
Abstract In this paper, we consider the stochastic heat equation of the form ∂ u ∂ t = Δ α u + ∂ 2 B...
It is generally argued that the solution to a stochastic PDE with multiplicative noise-such as , whe...
In this article we present a quantitative central limit theorem for the stochastic fractional heat e...
33 pages, 2 figuresMotivated by the modeling of three-dimensional fluid turbulence, we define and st...
Consider the stochastic heat equation ∂tu = (κ/2)∆u+ σ(u)F ̇ , where the solution u: = ut(x) is inde...
A fractional version of the heat equation, involving fractional powers of the negative Laplacian ope...
We define linear stochastic heat equations (SHE) on p.c.f.s.s. sets equipped with regular harmonic s...
We study the propagation of high peaks (intermittency fronts) of the solution to a stochastic heat e...
In this thesis, we study systems of linear and/or non-linear stochastic heat equations and fractiona...
2018-07-12The linear stochastic heat equation is often the starting point in the analysis of various...
We study the nonlinear stochastic heat equation in the spatial domain R, driven by space-time white ...
International audienceThe characterization of intermittency in turbulence has its roots in the K62 t...
Let u = {u(t, x), t ∈ [0, T ], x ∈ R d } be the solution to the linear stochastic heat equation driv...
Cette thèse est consacrée à l'étude de certaines classes d'équations aux dérivées partielles stocha...
International audienceWe consider the stochastic heat equation with multiplicative noise $u_t=\frac{...
Abstract In this paper, we consider the stochastic heat equation of the form ∂ u ∂ t = Δ α u + ∂ 2 B...
It is generally argued that the solution to a stochastic PDE with multiplicative noise-such as , whe...
In this article we present a quantitative central limit theorem for the stochastic fractional heat e...
33 pages, 2 figuresMotivated by the modeling of three-dimensional fluid turbulence, we define and st...
Consider the stochastic heat equation ∂tu = (κ/2)∆u+ σ(u)F ̇ , where the solution u: = ut(x) is inde...
A fractional version of the heat equation, involving fractional powers of the negative Laplacian ope...
We define linear stochastic heat equations (SHE) on p.c.f.s.s. sets equipped with regular harmonic s...
We study the propagation of high peaks (intermittency fronts) of the solution to a stochastic heat e...
In this thesis, we study systems of linear and/or non-linear stochastic heat equations and fractiona...
2018-07-12The linear stochastic heat equation is often the starting point in the analysis of various...
We study the nonlinear stochastic heat equation in the spatial domain R, driven by space-time white ...
International audienceThe characterization of intermittency in turbulence has its roots in the K62 t...
Let u = {u(t, x), t ∈ [0, T ], x ∈ R d } be the solution to the linear stochastic heat equation driv...
Cette thèse est consacrée à l'étude de certaines classes d'équations aux dérivées partielles stocha...
International audienceWe consider the stochastic heat equation with multiplicative noise $u_t=\frac{...
Abstract In this paper, we consider the stochastic heat equation of the form ∂ u ∂ t = Δ α u + ∂ 2 B...