Quantum Skyrmions in general quantum channels: topological noise rejection and the discretization of quantum information

TL;DR

This paper explores how topological properties of entangled photon states can provide robustness against noise in quantum information channels, potentially improving quantum communication and computation resilience.

Contribution

It introduces a topological noise model for entangled photons and demonstrates the resilience of topological quantum states against various noise types.

Findings

Topology provides resilience to non-depolarizing noise.

Discrete entanglement signals remain stable under depolarizing noise.

Homotopic maps show topological robustness to certain noise forms.

Abstract

The topology of a pure state of two entangled photons is leveraged to provide a discretization of quantum information. Since discrete signals are inherently more resilient to the effects of perturbations, this discrete class of entanglement observables may offer an advantage against noise. Establishing this is the primary objective of this paper. We develop a noise model that exploits the specific form of such topological wave functions - an entangled state of two photons with one in an orbital angular momentum state and the other in a polarization state. We show that noise affecting both photons can be recast as a position-dependent perturbation affecting only the photon in the polarization state. This approach allows us to utilize both the language and concepts used in studying noisy qubits, as well as recent advances in quantum polarimetry. By adding noise to a finite-dimensional Hilbert space of polarization states, we can describe the noise using quantum operations expressed through appropriate Krauss operators, whose structure is determined by quantum polarimetry. For non-depolarizing noise, we provide an argument based on homotopic maps that demonstrates the topology's resilience to noise. For depolarizing noise, numerical studies using the quantum channel description show that the discrete entanglement signal remains completely resilient. Finally, we identify sources of local noise that can destabilize the topology. This foundational work establishes a framework for understanding how topology enhances the resilience of quantum information, directly impacting the distribution of information through entanglement in noisy environments, such as quantum computers and quantum networks.