Efficient Magic State Distillation by Zero-Level Distillation

TL;DR

This paper introduces zero-level distillation, a method to produce high-fidelity magic states directly at the physical qubit level, significantly reducing overhead in fault-tolerant quantum computing.

Contribution

It proposes a novel zero-level distillation circuit using the Steane code on a square lattice, improving efficiency over traditional logical-level distillations.

Findings

Logical error rate scales as approximately 100 times the square of physical error rate

At p=10^{-4}, logical error rate reduces to 10^{-6}

Achieves 1-2 orders of magnitude improvement in error reduction

Abstract

Magic state distillation (MSD) is an essential element for universal fault-tolerant quantum computing, which distills a high-fidelity magic state from noisy magic states using ideal (error-corrected) Clifford operations. For ideal Clifford operations, it needs to be performed on the logical qubits and hence incurs a large spatiotemporal overhead, which is one of the major bottlenecks for the realization of fault-tolerant quantum computers (FTQCs). Here we propose zero-level distillation, which prepares a high-fidelity logical magic state at the physical level, namely zero level, using physical qubits and nearest-neighbor two-qubit gates on a square lattice. We develop a zero-level distillation circuit and show that distillation can be made even more efficient than the conventional sophisticated approaches with logical level distillations. The key idea involves the Knill et al.-type distillation using the Steane code and its careful mapping to the square-lattice architecture with error detection. The distilled magic state on the Steane-code state is then teleported or converted to surface codes. We numerically find that the error rate of the logical magic state scales as approximately $100 \times p^{2}$ in terms of the physical error rate $p$. For example, with a physical error rate of $p = 10^{-4}$ ($10^{-3}$), the logical error rate is reduced to $p_{L} = 10^{-6}$ ($10^{-4}$), resulting in an improvement of 2 (1) orders of magnitude. This contributes to reducing both space and time overhead for early FTQC as well as full-fledged FTQC combined with conventional multilevel distillation protocols.