Experimental noiseless quantum amplification of coherent states of light by two-photon addition and subtraction

TL;DR

This paper demonstrates an experimental implementation of a noiseless quantum amplifier for coherent light states using a sequence of two-photon addition and subtraction, advancing quantum state engineering capabilities.

Contribution

It introduces a novel approach of using multiple photon additions and subtractions for noiseless amplification, offering an efficient alternative to multiplexing.

Findings

High fidelity amplification observed

Agreement with theoretical models confirmed

Sequence of photon operations enhances quantum state control

Abstract

Noiseless quantum amplifiers are probabilistic quantum devices that enhance amplitude of coherent states without adding any noise, which has far reaching applications in quantum optics and quantum information processing. Here, we report on experimental implementation of an advanced noiseless quantum amplifier for coherent states of light that is based on conditional addition of two photons followed by conditional subtraction of two photons. We comprehensively characterize the noiselessly amplified coherent states via quantum state tomography and analyze the amplification gain and noise properties of the amplifier. We observe very good agreement between the experiment and theoretical predictions. Our work reveals that sequences of multiple photon additions and subtractions represent an efficient and experimentally feasible alternative to multiplexing that was originally proposed to boost the performance of noiseless quantum amplifiers. Beyond noiseless quantum amplification, our experiment represents a significant step forward towards engineering complex quantum operations on traveling light beams by coherent combinations of various sequences of multiphoton additions and subtractions.