Topological terms with qubit regularization and relativistic quantum circuits

TL;DR

This paper explores a novel qubit regularization scheme for quantum field theories, revealing rich phase diagrams including a critical phase described by the Wess-Zumino-Witten conformal field theory, and introduces relativistic quantum circuits for real-time physics simulation.

Contribution

It introduces the SU(3)-F qubit regularization scheme embedding SO(3) symmetry and constructs a lattice model demonstrating critical and massive phases, including a relativistic quantum circuit framework.

Findings

Identified a critical phase described by the k=1 WZW CFT.

Discovered a first-order transition between critical and massive phases.

Developed a relativistic quantum circuit for real-time physics simulation.

Abstract

Qubit regularization provides a rich framework to explore quantum field theories. The freedom to choose how the important symmetries of the theory are embedded in the qubit regularization scheme allows us to construct new lattice models with rich phase diagrams. Some of the phases can contain topological terms which lead to critical phases. In this work we introduce and study the SU(3)-F qubit regularization scheme to embed the SO(3) spin-symmetry. We argue that qubit models in this regularization scheme contain several phases including a critical phase which describes the k = 1 Wess-Zumino-Witten (WZW) conformal field theory (CFT) at long distances, and two massive phases one of which is trvially gapped and the other which breaks the lattice translation symmetry. We construct a simple space-time Euclidean lattice model with a single coupling U and study it using the Monte Carlo method. We show the model has a critical phase at small U and a trivially massive phase at large U with a first order transition separating the two. Another feature of our model is that it is symmetric under space-time rotations, which means the temporal and spatial lattice spacing are connected to each other. The unitary time evolution operator obtained by a Wick rotation of the transfer matrix of our model can help us compute the physics of the k = 1 WZW CFT in real time without the need for tuning the temporal lattice spacing to zero. We use this idea to introduce the concept of a relativistic quantum circuit on a discrete space-time lattice.