Detecting screens modeled by Schrödinger operators that generate C0 contraction semigroups

Abstract

Consider a non-relativistic quantum particle with wave function ψ in a bounded C2 region Ω⊂ Rn, and suppose detectors are placed along the boundary ∂ Ω. Assume the detection process is irreversible, its mechanism is time independent and also hard, i.e., detections occur only along the boundary ∂ Ω. Under these conditions Tumulka informally argued that the dynamics of ψ must be governed by a C0 contraction semigroup that weakly solves the Schrödinger equation and proposed modeling the detector by a time-independent local absorbing boundary condition at ∂ Ω. In this paper, we apply the newly discovered theory of boundary quadruples to parameterize all C0 contraction semigroups whose generators extend the Schrödinger Hamiltonian, and prove a variant of Tumulka's claim: all such evolutions are generated by the placement of a linear absorbing boundary condition on ψ along ∂ Ω. We combine this result with the work of Werner to show that each C0 contraction semigroup naturally admits a Born rule for the time of detection along ∂ Ω, and we prove that a detection will almost surely occur in finite time if detectors have been placed everywhere along ∂ Ω.

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