Geometric constructions of generalized dual-unitary circuits from biunitarity

TL;DR

This paper introduces a geometric framework for constructing solvable quantum lattice models with multiple unitary directions, unifying various dual-unitary constructions and exploring their entanglement and correlation properties.

Contribution

It develops a general biunitary connection framework on the Kagome lattice to create multi-unitary circuits with hierarchical structures and solvable dynamics, extending previous models.

Findings

Unifies dual-unitary and triunitary gate constructions

Introduces multilayer circuits with higher hierarchical solvability

Discusses ergodicity and non-ergodicity in new models

Abstract

We present a general framework for constructing solvable lattice models of chaotic many-body quantum dynamics with multiple unitary directions using biunitary connections. We show that a network of biunitary connections on the Kagome lattice naturally defines a multi-unitary circuit, where three `arrows of time' directly reflect the lattice symmetry. These models unify various constructions of hierarchical dual-unitary and triunitary gates and present new families of models with solvable correlations and entanglement dynamics. Using multilayer constructions of biunitary connections, we additionally introduce multilayer circuits with monoclinic symmetry and higher level hierarchical dual-unitary solvability and discuss their (non-)ergodicity. Our work demonstrates how different classes of solvable models can be understood as arising from different geometric structures in spacetime.