PML method for the time-domain stochastic acoustic wave equation and an inverse source problem

In this paper, we develop and analyze a time-domain perfectly matched layer (PML) method for the stochastic acoustic wave equation driven by spatially white additive Gaussian noise. We begin by establishing the well-posedness and stability of the direct problem through a rigorous analysis of the associated time-harmonic stochastic Helmholtz equation and the application of an abstract Laplace transform inversion theorem. To address the low regularity of the random source, we employ scattering theory to investigate the meromorphic continuation of the Helmholtz resolvent defined on rough fields. Based on a piecewise constant approximation of the white noise, we construct an approximate wave solution and formulate a time-domain PML method. The convergence of the PML method is established, with explicit dependence on the PML layer's thickness and medium properties, as well as the piecewise constant approximation of the white noise. In addition, we propose a frequency-domain approach for solving the inverse random source problem using time-domain boundary measurements. A logarithmic stability estimate is derived, highlighting the ill-posedness of the inverse problem and offering guidance for the design of effective numerical schemes.