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

Often quantum computational models can be understood via the lens of resource theories, where a computational advantage is achieved by consuming specific forms of quantum resources and, conversely, resource-free computations are classically simulable. For example, circuits of nearest-neighbor matchgates can be mapped to free-fermion dynamics, which can be simulated classically. Supplementing these circuits with nonmatchgate operations or non-gaussian fermionic states, respectively, makes them quantum universal. Can we similarly identify quantum computational resources in the setting of more general quasi-particle statistics, such as that of fermionic anyons? In this work, we develop a resource-theoretic framework to define and investigate the separability of fermionic anyons. We build the notion of separability through a fractional Jordan-Wigner transformation, leading to a Schmidt decomposition for fermionic-anyon states. We show that this notion of fermionic-anyon separability, and the unitary operations that preserve it, can be mapped 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. Though this does not coincide with the usual definition of qubit entanglement, it provides new insight into the limited capabilities of matchgate circuits.