Existence of Schrodinger Evolution with Absorbing Boundary Condition

Abstract

Consider a non-relativistic quantum particle with wave function inside a region ⊂ R3, and suppose that detectors are placed along the boundary ∂ . The question how to compute the probability distribution of the time at which the detector surface registers the particle boils down to finding a reasonable mathematical definition of an ideal detecting surface; a particularly convincing definition, called the absorbing boundary rule, involves a time evolution for the particle's wave function expressed by a Schr\"odinger equation in together with an ``absorbing'' boundary condition on ∂ first considered by Werner in 1987, viz., ∂ /∂ n=i with >0 and ∂/∂ n the normal derivative. We provide here a discussion of the rigorous mathematical foundation of this rule. First, for the viability of the rule it plays a crucial role that these two equations together uniquely define the time evolution of ; we point out here how, under some technical assumptions on the regularity (i.e., smoothness) of the detecting surface, the Lumer-Phillips theorem implies that the time evolution is well defined and given by a contraction semigroup. Second, we show that the collapse required for the N-particle version of the problem is well defined. We also prove that the joint distribution of the detection times and places, according to the absorbing boundary rule, is governed by a positive-operator-valued measure.