Path-integral approach to the Schrödinger current

Abstract

Discontinuous initial wave functions, or wave functions with a discontinuous derivative and a bounded support, arise in a natural way in various situations in physics, in particular in measurement theory. The propagation of such initial wave functions is not well described by the Schr\odinger current which vanishes on the boundary of the support of the wave function. This propagation gives rise to a unidirectional current at the boundary of the support. We use path integrals to define current and unidirectional current, and to provide a direct derivation of the expression for current from the path-integral formulation for both diffusion and quantum mechanics. Furthermore, we give an explicit asymptotic expression for the short-time propagation of an initial wave function with compact support for cases of both a discontinuous derivative and a discontinuous wave function. We show that in the former case the probability propagated across the boundary of the support in time $\ensuremath{\Delta}t$ is $O(\ensuremath{\Delta}{t}^{3/2}),$ and the initial unidirectional current is $O(\ensuremath{\Delta}{t}^{1/2}).$ This recovers the Zeno effect for continuous detection of a particle in a given domain. For the latter case the probability propagated across the boundary of the support in time $\ensuremath{\Delta}t$ is $O(\ensuremath{\Delta}{t}^{1/2}),$ and the initial unidirectional current is $O(\ensuremath{\Delta}{t}^{\ensuremath{-}1/2}).$ This is an anti-Zeno effect. However, the probability propagated across a point located at a finite distance from the boundary of the support is $O(\ensuremath{\Delta}t).$ This gives a decay law.