Efficient Magic State Cultivation on $\mathbb{RP}^2$
Abstract
Preparing high-fidelity logical magic states is crucial for fault-tolerant quantum computation. Among prior attempts to reduce the substantial cost of magic state preparation, magic state cultivation (MSC), a recently proposed protocol for preparing states without magic state distillation, achieves state-of-the-art efficiency. Inspired by this work, we propose a new MSC procedure that would produce a logical state on a rotated surface code at a further reduced cost. For our MSC protocol, we define a new code family, the code, by putting the rotated surface code on (a two-dimensional manifold), as well as two self-dual CSS codes named SRP-3 and SRP-5 respectively. Small codes are used to hold logical information and checked by syndrome extraction (SE) circuits. We design fast morphing circuits that enable switching between a distance 3 (5) code and an SRP-3 (SRP-5) code on which we can efficiently check the correctness of the logical state. To preserve the high accuracy of the cultivated logical state, we design an efficient and easy-to-decode expansion stage that grows a small code to a large rotated surface code in one round. Our MSC protocol utilizes non-local connectivity, available on both neutral atom array and ion trap platforms. According to our Monte Carlo sampling results, our MSC protocol requires about an order of magnitude smaller space-time volume to reach a target logical error rate around compared to the original MSC protocol.
Keywords
Cite
@article{arxiv.2503.18657,
title = {Efficient Magic State Cultivation on $\mathbb{RP}^2$},
author = {Zi-Han Chen and Ming-Cheng Chen and Chao-Yang Lu and Jian-Wei Pan},
journal= {arXiv preprint arXiv:2503.18657},
year = {2025}
}
Comments
15 pages, 14 figures