Experimental demonstration of optimal probabilistic enhancement of quantum coherence

TL;DR

This paper demonstrates both theoretically and experimentally how probabilistic quantum filtering can optimally enhance the coherence of quantum states, with potential applications in quantum information processing.

Contribution

It introduces the concept of optimal quantum filters for coherence enhancement and verifies their effectiveness through a linear optical experiment.

Findings

Optimal filters maximize output coherence for given success probability

Experimental validation of quantum coherence enhancement

Full quantum process tomography confirms filter performance

Abstract

We theoretically and experimentally investigate conditional enhancement of overall coherence of quantum states by probabilistic quantum operations that apply to the input state a quantum filter diagonal in the basis of incoherent states. We identify the optimal filters that for a given probability of successful filtering maximize the output coherence. We verify the performance of the studied quantum filters in a proof-of-principle experiment with linear optics, where a pair of two-level quantum systems is represented by polarization states of two photons. We comprehensively characterize the implemented two-qubit linear optical quantum filters by full quantum process tomography and we experimentally observe the optimal quantum coherence enhancement by quantum filtering.