Constant-Depth Clifford-Hierarchy Gates via Non-Abelian Surface Codes

Abstract

We present an entirely 2D constant-depth realization of topologically protected phase gates at any level of the Clifford hierarchy, and beyond, using non-Abelian surface codes. Our construction encodes a logical qubit in the quantum double D(G) of a non-Abelian group G on a triangular spatial patch. The logical gate is implemented by a constant-depth circuit constructed from stacking on the spatial region a symmetry-protected topological (SPT) phase specified by a group 2-cocycle and boundary counter-terms. The Bravyi--König theorem limits the unitary gates implementable by constant-depth quantum circuits on Pauli stabilizer codes in D dimensions to the D-th level of the Clifford hierarchy. We bypass this limitation, by constructing constant-depth unitary gates at arbitrary levels of the Clifford hierarchy purely in 2D, without sacrificing locality or fault tolerance, at the cost of using the quantum double of a non-Abelian group G. Specifically, for G = D4N, the dihedral group of order 8N, we realize the phase gate T1/N = diag(1, eiπ/(4N)) in the logical Z basis. In this context, we propose a non-abelian stabilizer group formalism, which we work out for dihedral groups. For 8N = 2n, the logical gate lies at the n-th level of the Clifford hierarchy and, importantly, has a qubit-only realization: we show that it can be constructed in terms of Clifford-hierarchy stabilizers for a code with n physical qubits on each edge of the lattice. We also discuss code-switching to the double surface-code D(Z2×Z2), to complete a universal gate-set in this setup.