Entanglement of Vector-Polarization States of Photons

TL;DR

This paper introduces a new class of vector-polarization entangled Bell states of photons, utilizing space-variant polarization structures and a Sagnac interferometer, enhancing quantum information capacity.

Contribution

It presents the theoretical creation and analysis scheme for vector-polarization entangled Bell states, expanding the degrees of freedom for quantum entanglement.

Findings

Proposed a scheme using a Sagnac interferometer for creating vector-polarization entangled states.

Designed an analyzer for identifying these complex entangled states.

Highlights potential for increased information capacity in quantum communication.

Abstract

Photons may have homogeneous polarization and may carry quantized orbital angular momentum (OAM). Photon entanglement has been realized in various degrees of freedom such as polarization and OAM. Using a pair of orthogonally polarized states carrying opposite-handedness quantized OAMs could create "quantized" vector polarization states with space-variant polarization structures. It is thus possible to extend the polarization degree of freedom from two dimensional space to indefinite dimensional discrete Hilbert space. We present a class of vector-polarization entangled Bell states, which use the spatial modes of the vector fields with space-variant polarization structure. We propose a scheme of creating the vector-polarization entangled Bell states using a Sagnac interferometer. We also design an analyzer for identifying the vector-polarization entangled Bell states. Such a class of entanglement is important for quantum information science and technology, and fundamental issues of quantum theory, due to its advantage of the increase in information capacity.