Single photon wavefront characterization by optical mixing

TL;DR

This paper proposes a method to characterize the wavefront of a single photon by enhancing optical mixing sensitivity through intensity correlation measurements, enabling wavefront sensing at multiple locations.

Contribution

It introduces a novel approach combining optical mixing and intensity correlation to improve single photon wavefront characterization at multiple points.

Findings

Enhanced sensitivity in single photon wavefront detection.

Feasibility demonstrated through a simple quantum model.

Alignment with previous experimental results.

Abstract

Optical mixing experiments show the ability of amplifying a weak optical signal by superposing it with a stronger one. This principle has been demonstrated also for weak signals at the quantum level, down to a single photon. In the present communication it is suggested that the sensitivity of optical mixing between a strong macroscopic source and a single photon can be further enhanced as to allow the sensing the wavefront of the photon's mode simultaneously at two or more locations. Key conditions for that detection is reducing the active size of the detectors below the typical size of the transverse modes, and performing an optical intensity correlation measurement of the Hanbury Brown and Twiss type. Due to the inherent amplification effect of the mixing process, a macroscopic signal is extracted, out of which the photon wave-front characterization at more than one location is achievable with good fidelity even for a single photon emission event. A basic scheme is proposed for the demonstration of the effect, which is analyzed based on a simple quantum model. The validity of the model is confirmed by comparison with previous theoretical and experimental reports involving single photon sources.