English

Fermionic anyons: entanglement and quantum computation from a resource-theoretic perspective

Quantum Physics 2024-07-15 v2

Abstract

Quantum computational models can be approached via the lens of resources needed to perform computational tasks, where a computational advantage is achieved by consuming specific forms of quantum resources, or, conversely, resource-free computations are classically simulable. Can we similarly identify quantum computational resources in the setting of more general quasi-particle statistics? In this work, we develop a framework to characterize the separability of a specific type of one-dimensional quasiparticle known as a fermionic anyon. As we evince, the usual notion of partial trace fails in this scenario, so we build the notion of separability through a fractional Jordan-Wigner transformation, leading to an entanglement description of fermionic-anyon states. We apply this notion of fermionic-anyon separability, and the unitary operations that preserve it, mapping it to the free resources of matchgate circuits. We also identify how entanglement between two qubits encoded in a dual-rail manner, as standard for matchgate circuits, corresponds to the notion of entanglement between fermionic anyons.

Keywords

Cite

@article{arxiv.2306.00795,
  title  = {Fermionic anyons: entanglement and quantum computation from a resource-theoretic perspective},
  author = {Allan Tosta and Antônio C. Lourenço and Daniel Brod and Fernando Iemini and Tiago Debarba},
  journal= {arXiv preprint arXiv:2306.00795},
  year   = {2024}
}

Comments

5+18 pages, 2 figures. Addition of a new Theorem about fermionic-anyons single-particle entanglement, as well as minor text revisions. Comments are welcome

R2 v1 2026-06-28T10:53:30.490Z