Parity-unfolded distillation architecture for noise-biased platforms

Abstract

We introduce the parity-unfolded architecture, a fault-tolerant quantum computing scheme that relies on direct preparation and teleportation of small-angle rotations Z1/2k rather than approximating them with the conventional (Clifford + T) gate set. The architecture is enabled by efficient distillation of gates from an arbitrary level of the Clifford hierarchy, which we refer to as parity unfolding. With it, a state |Zk = Z1/2k|+ can be prepared fault-tolerantly using 2k+3 + O(2k/2) biased-noise qubits on a planar chip with nearest-neighbour connectivity. For algorithms requiring native Z1/2k gates, such as the Quantum Fourier Transform and phase estimation, the proposed scheme allows to reduce resource overheads for up to k=7, i.e., up to T1/32. Furthermore, when used for the synthesis of arbitrary small-angle rotations, parity-unfolded distillation of (T + T) reduces the minimum achievable logical error rate by 43% while cutting the resource requirements by 26%, when compared to unfolded distillation of only the T gate.