Controlled jump in the Clifford hierarchy

Abstract

We develop a simple and systematic route to higher levels of the qubit Clifford hierarchy by coherently controlling Clifford operations. Our approach is based on Pauli periodicity, defined for a Clifford unitary U as the smallest integer m 1 such that U2m is a Pauli operator up to phase. We prove a sharp controlled-jump rule showing that the controlled gate CU lies strictly in level m+2 of the hierarchy, and equivalently that CU lies in level k if U2k-2 is Pauli while no smaller positive power of U is Pauli. We further quantify the resources required to realize large level jumps in the Clifford hierarchy by proving an essentially tight upper bound on Pauli periodicity as a function of the number of qubits, which implies that accessing high hierarchy levels through controlled Cliffords requires a number of target qubits that grows exponentially with the desired level. We complement this limitation with explicit infinite families of Pauli-periodic Cliffords whose controlled versions achieve asymptotically optimal jumps. As an application, we propose a protocol for preparing logical catalyst states that enable logical Z1/2k phase gates via phase kickback from a single jumped Clifford.