Spin-Momentum Impedance and Filtering by a Spin-Coupled Absorbing Boundary Condition

Abstract

Absorbing boundaries are often treated as scalar sinks. Here we show that a spin-coupled absorbing boundary for a Pauli particle acts instead as a spin--momentum impedance. Its tangential boundary symbol has two branches, iκ|ξ|, coupling normal absorption to in-plane momentum. In a harmonic guide, the transverse ground state samples |ξ| -1ω; narrowing the guide therefore strengthens a local evanescent boundary response without introducing a bulk potential barrier. Solving the detector-present spinor absorbing-boundary evolution, we identify boundary-induced filtering: the prompt detector flux is suppressed, the fixed-window detected fraction is reduced, and a delayed oscillatory sector appears. Over that window the restricted mean detection time is fitted by A+Bω, with setup-dependent coefficients. The robust result is a spin--momentum filtering mechanism with boundary scale |ξ|ω, not a universal arrival-time law.