The paraxial approximation in quantum optics I: Henochromatic modes of a scalar field

TL;DR

This paper investigates the association between paraxial beam modes and quantum states, emphasizing the importance of inner product relationships and identifying a unique, unitary mapping to henochromatic quantum states.

Contribution

It demonstrates that the mapping of paraxial beam modes to henochromatic quantum states is uniquely well suited and mathematically unitary, clarifying mode-state correspondence in quantum optics.

Findings

The inner product used for beam mode expansion is crucial for quantum state association.

Among proposed mappings, the henochromatic state mapping is uniquely unitary.

The analysis clarifies the mode-to-state correspondence in the paraxial approximation.

Abstract

This paper examines how best to associate quantum states of a single particle to different modes of a narrowly collimated beam of classical radiation modeled in the paraxial approximation. Our analysis stresses the importance of the relationship between two inner products naturally arising in the problem. These are the inner product used to expand a general beam as a superposition of orthogonal modes in the paraxial approximation, on the one hand, and the canonical inner product on which the statistical interpretation of quantum (field) theory is founded, on the other. While several candidates for the sort of association between beam modes and single-particle quantum states have been proposed in the literature, here we argue that one of them is uniquely well suited to the task. Specifically, the mapping of beam modes to the ``henochromatic'' quantum states previously introduced by Sudarshan, Simon and Mukunda is unique within a large class of similar mappings in that it is unitary in a mathematically precise sense.