Universal Computation with Quantum Fields

TL;DR

This paper introduces a universal quantum computation method using particles with unique exchange properties, demonstrating its universality, analyzing phase transitions, and exploring applications like adiabatic quantum computation and Majorana fermion systems.

Contribution

It presents a novel approach to universal quantum computation with non-bosonic, non-fermionic particles and analyzes phase transitions using OTOC, expanding quantum computational frameworks.

Findings

Demonstrates universality of the proposed quantum computation method.

Shows that non-stoquastic evolution avoids first-order phase transitions.

Uses OTOC to successfully diagnose phase transitions.

Abstract

We explore a way of universal quantum computation with particles which cannot occupy the same position simultaneously and are symmetric under exchange of particle labels. Therefore the associated creation and annihilation operators are neither bosonic nor fermionic. In this work we first show universality of our method and numerically address several examples. We demonstrate dynamics of a Bloch electron system from a viewpoint of adiabatic quantum computation. In addition we provide a novel Majorana fermion system and analyze phase transitions with spin-coherent states and the time average of the OTOC (out-of-time-order correlator). We report that a first-order phase transition is avoided when it evolves in a non-stoquastic manner and the time average of the OTOC diagnoses the phase transitions successfully.