First-order linear evolution equations with c\`adl\`ag-in-time solutions

Abstract

In this work we study first-order linear parabolic evolution PDEs over Rd×R and Rd×R+ comprising a spatial operator defined through a symbol function and a source term such that its spatial Fourier transform is a slow-growing measure over Rd×R. When the source term is required to has its support on Rd×R+, it is shown that there exists a unique solution such that its spatial Fourier transform is a slow-growing measure with support in Rd×R+, which in addition has a c\`adl\`ag-in-time behaviour. This allows to well-pose and analyse an initial value problem associated to this class of equations and to consider cases where the spatial operator can be a pseudo-differential operator. We also look at for solutions to the cases where the source term is such that its spatial and spatio-temporal Fourier transforms are slow-growing measures over Rd×R. In such a case, it is shown that when the real part of the symbol function of the spatial operator is inferiorly bounded by a strictly positive constant, there exists a unique solution whose both spatial and spatio-temporal Fourier transforms are slow-growing measures over Rd×R, and which also has a c\`adl\`ag-in-time behaviour. In addition, it is proven that the solution to an associated Cauchy problem converges spatio-temporally asymptotically to this unique solution as the time flows long enough.