Distinguishing limit of Bell states for any $n$-photon $D$-dimensional hyperentanglement

TL;DR

This paper establishes the theoretical limits for distinguishing Bell states in multi-photon, high-dimensional hyperentangled systems and designs an optical setup to distinguish a significant subset, enhancing quantum communication capacity.

Contribution

It derives the maximum number of Bell states distinguishable in $n$-photon $D$-dimensional hyperentanglement and proposes a practical optical setup for two-photon eight-dimensional Bell state measurement.

Findings

Derived the limit ${N_1} = nD - (n - 1)$ for distinguishable Bell states.

Proved at least ${D^{n - 1}}$ Bell states can be distinguished due to symmetry.

Designed an optical setup to distinguish 15 classes of 64 Bell states in two-photon 8D hyperentanglement.

Abstract

Bell state measurement is crucial to quantum information protocols, but it is impossible to unambiguously distinguish all the Bell states encoded in multi-photon using only linear optics. There is a maximum number of distinguished Bell states, i.e. distinguising limit which is very important for increasing the channel capacity of quantum communications. In this paper, we separate $n$-photon $D$-dimensional hyperentanglement into two groups. For the first group of $U$ ($G_1$), we obtain the limit ${N_1} = nD - (n - 1)$, which can be applied for both bosons' and fermions' cases. We further discuss the limit $N$ for any $nD$ system with the second group of $U$ ($G_2$), inferring that at least ${D^{n - 1}}$ Bell states can be distinguished due to the symmetry of Bell states. Obviously, ${N_1} \le {N_2}$ for those systems with $n>2$. Finally, we theoretically design an optical setup for Bell state measurement of two-photon eight-dimensional hyperentanglement of spin, path and orbital angular momentum (OAM) and distinguish 15 classes of 64 Bell states. Our results provide a theoretical basis and practical reference to increase the channel capacity of the quantum communication.