Atomic state interferometry for complex vector light

TL;DR

This paper explores how complex vector light influences atomic state interferometry, revealing new ways to control optical absorption through polarization and magnetic field geometry, with potential applications in quantum sensing.

Contribution

It provides a fully analytical model of structured light interacting with a four-state atomic system, highlighting spatially dependent dark states and absorption control mechanisms.

Findings

Identification of spatially dependent dark states.

Analysis of structured light effects like polarization vortices.

Enhanced understanding of polarization and magnetic field influence.

Abstract

Features of complex vector light become important in any interference effects, including scattering, diffraction, and non-linear processes. Here we are investigating the role of polarization-structured light in atomic state interferometers. Unlike optical or atomic path interferometers, these facilitate local interference between atomic transition amplitudes and hence the orthogonal optical polarization components driving these transitions. We develop a fully analytical description for the inter action of generalized structured light with an atomic four state system, that is multiply connected via optical as well as magnetic transitions. Our model allows us to identify spatially dependent dark states, associated with spatially structured absorption coefficients, which are defined by the geometry of the polarization state and the magnetic field direction. We illustrate this for a range of optical beams including polarization vortices, optical skyrmions and polarization lattices. This results in a new interpretation and an enhanced understanding of atomic state interferometry, and a versatile mechanism to modify and control optical absorption as a function of polarization and magnetic field alignment.