Non-Clifford symmetry protected topological higher-order cluster states in multi-qubit measurement-based quantum computation

Abstract

A cluster state is a strongly entangled state, which is a source of measurement-based quantum computation. It is generated by applying controlled-Z (CZ) gates to the state ++·s + . It is protected by the Z2even× Z2 odd symmetry. By applying general quantum gates to the state ++·s + , we systematically obtain a general short-range entangled cluster state. If we use a non-Clifford gate such as the controlled phase-shift gate, we obtain a non-Clifford cluster state. Furthermore, if we use the controlled-controlled Z (CCZ) gate instead of the CZ gate, we obtain non-Clifford cluster states with five-body entanglement. We generalize it to the CNZ gate, where (2N+1)-body entangled states are generated. The Z2even× Z2odd symmetry is non-Clifford for N≥ 3. We demonstrate that there emerge 22N fold degenerate ground states for an open chain, indicating the emergence of N free spins at each edge. They can be used as an N-qubit input and an N-qubit output in measurement-based quantum computation. We also study the non-invertible symmetry, the Kennedy-Tasaki transformation and the string-order parameter in addition to the Z2even× Z2odd symmetry in these models.