Multiphoton states engineering by heralded interference via six-port Mach-Zehnder interferometer

TL;DR

This paper presents a method to generate diverse multiphoton nonclassical states using heralded interference in a six-port Mach-Zehnder interferometer, demonstrating significant quadrature-squeezing effects with controllable parameters.

Contribution

It introduces a novel protocol for creating multiple types of multiphoton states via heralded interference, manipulating single-photon levels in a six-port interferometer.

Findings

Generated sixteen types of multiphoton nonclassical states.

Achieved maximum quadrature-squeezing of 2.57dB.

Success probability for maximum squeezing is 6.7%.

Abstract

Based on heralded interference on a six-port Mach-Zehnder interferometer, we propose protocols to generate a series of multiphoton states in primary output port, by injecting a coherent state in primary input port and two Fock states in two ancillary input ports, and measuring two Fock states in two ancillary output ports. Only manipulating at the single-photon level (i.e, |0> or |1>) in all ancillary ports, we generate sixteen types (six categories) of multiphoton nonclassical states, whose state vectors are unified as superposition of a new coherent state, a single-photon added coherent state, and a two-photon added coherent state. Indeed, a wide range of nonclassical phenomena can be created by modulating the interaction parameters (including coherent field strength and shift phase). We mainly analyze quadrature-squeezing effects for all our considered states. Of particular interest is maximum squeezing of up to 2.57dB, with success probability 6.7%, at least in our present cases.