Classical and Quantum Light: Versatile tools for quantum foundations and quantum information

TL;DR

This thesis demonstrates the versatility of classical and quantum light in exploring quantum foundations and information, including simulations of relativistic particles, measurement theory, and quantum channel implementations.

Contribution

It presents novel experiments and theoretical insights into classical-quantum analogies, quantum steering, and quantum channel realization using light's degrees of freedom.

Findings

Classical light can simulate relativistic quantum dynamics.

Effective discrete measurements can be constructed from continuous variables.

Experimental realization of quantum channels with single photons.

Abstract

Light beams offer many degrees of freedom to be explored in discrete and continuous domains. In addition to the possibility of entangling photons in these many degrees of freedom, it makes light a very useful and versatile tool for quantum information and quantum foundation purposes. In this thesis, we endorse its importance and versatility by presenting novel contributions that further explore both discrete and continuous degrees of freedom. It begins with two experiments that use classical light and explore its analogous behavior to quantum systems. The first one is a classical optics simulation of the dynamics of a relativistic quantum particle. The second work is related to the theory of mutually unbiased measurements that are effectively discrete but constructed from continuous variables systems. In the second part of the thesis, three works are presented that use the polarization and path discrete degrees of freedom. The first one is a redefinition of the quantum nonlocal correlation called steering in the multipartite scenario, based on an inconsistency in the previous definition, namely the creation of this correlation from scratch using operations that supposedly would not be able to do so. We call this exposure of quantum steering. Steering exposure is observed with entangled photons. The other two works are related to the experimental implementation of quantum channels of qubits, one of them is a particular channel for which we test for non-Markovianity using a operational measure called conditional past-future (CPF) correlation. The thesis finishes with a proposal for an experimental realization of any quantum channel of a single qubit, where the qubit is realized by the polarization of single photons. The functioning of all optical devices used is didactically explained.