Stochastically switching diffusion with partially reactive surfaces

Abstract

In this paper we develop a hybrid version of the encounter-based approach to diffusion-mediated absorption at a reactive surface, which takes into account stochastic switching of a diffusing particle's conformational state. For simplicity, we consider a two-state model in which the probability of surface absorption depends on the current particle state and the amount of time the particle has spent in a neighborhood of the surface in each state. The latter is determined by a pair of local times n,t, n=0,1, which are Brownian functionals that keep track of particle-surface encounters over the time interval [0,t]. We proceed by constructing a differential Chapman-Kolmogorov equation for a pair of generalized propagators Pn(,0,1,t), where Pn is the joint probability density for the set (t,0,t,1,t) when Nt=n, where t denotes the particle position and Nt is the corresponding conformational state. Performing a double Laplace transform with respect to 0,1 yields an effective system of equations describing diffusion in a bounded domain , in which there is switching between two Robin boundary conditions on ∂ . The corresponding constant reactivities are j=D zj, j=0,1, where zj is the Laplace variable corresponding to j and D is the diffusivity. Given the solution for the propagators in Laplace space, we construct a corresponding probabilistic model for partial absorption, which requires finding the inverse Laplace transform with respect to z0,z1. We illustrate the theory by considering diffusion of a particle on the half-line with the boundary at x=0 effectively switching between a totally reflecting and a partially absorbing state. Finally, we indicate how to extend the analysis to higher spatial dimensions using the spectral theory of Dirichlet-to-Neumann operators.

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