Clifford quantum cellular automata from topological quantum field theories and invertible subalgebras

Abstract

We present a general framework for constructing quantum cellular automata (QCA) from topological quantum field theories (TQFT) and invertible subalgebras (ISA) using the cup-product formalism. This approach explicitly realizes all Z2 and Zp Clifford QCAs (for prime p) in all admissible dimensions, in precise agreement with the classification predicted by algebraic L-theory. We determine the orders of these QCAs by explicitly showing that finite powers reduce to the identity up to finite-depth quantum circuits (FDQC) and lattice translations. In particular, we demonstrate that the Z2 Clifford QCAs in (4l+1) spatial dimensions can be disentangled by non-Clifford FDQCs. Our construction applies beyond cubic lattices, allowing Z2 QCAs to be defined on arbitrary cellulations. Furthermore, we explicitly construct invertible subalgebras in higher dimensions, obtaining Z2 ISAs in 2l spatial dimensions and Zp ISAs in (4l-2) spatial dimensions. These ISAs give rise to Z2 QCAs in (2l+1) dimensions and Zp QCAs in (4l-1) dimensions. We further prove that the QCAs in 3 spatial dimensions constructed via TQFTs and ISAs are equivalent by identifying their boundary algebras, and show that this approach extends to higher dimensions. Together, these results establish a unified and dimension-periodic framework for Clifford QCAs, connecting their explicit lattice realizations to field theories.