Waveguides in a quantum perspective

TL;DR

This paper develops a comprehensive quantum theory for waveguides used in solid-state quantum devices, analyzing mode families, their physical interpretation, and quantum noise characteristics.

Contribution

It provides a full quantum description of waveguide modes, extending potential difference concepts, and predicts quantum noise levels for different modes.

Findings

TM modes exhibit lower quantum noise than higher modes

Quantum zero-point fluctuations are computed for various configurations

Low-noise modes could enhance quantum information routing

Abstract

Solid state quantum devices, operated at dilution cryostat temperatures, are relying on microwave signals to both drive and read-out their quantum states. These signals are transmitted into the cryogenic environment, out of it towards detection devices, or even between quantum systems by well-designed waveguides, almost lossless when made of superconducting materials. Here we report on the quantum theory that describes the simplest Cartesian-type geometries: parallel plates, and rectangular tubes. The aim of the article is twofold: first on a technical and pragmatic level, we provide a full and compact quantum description of the different traveling wave families supported by these guides. Second, on an ontological level, we interpret the results and discuss the nature of the light fields corresponding to each mode family. The concept of potential difference is extended from transverse electric-magnetic (TEM) waves to all configurations, by means of a specific gauge fixing. The generalized flux $\phi$ introduced in the context of quantum electronics becomes here essential: it is the scalar field, conjugate of a charge $Q$, that confines light within the electrodes, let them be real or virtual. The gap in the dispersion relations of non-TEM waves turns out to be linked either to a potential energy necessary for the photon confinement, or to a kinetic energy arising from a photon mass. We finally compute the field zero-point fluctuations in every configuration. The theory is predictive: the lowest transverse magnetic (TM) modes should have smaller quantum noise than the higher ones, which at large wavevectors recover a conventional value similar to TEM and transverse electric (TE) ones. Such low-noise modes might be particularly useful for the routing of quantum information.