Factoring integers with sublinear resources on a superconducting quantum processor
Abstract
Shor's algorithm has seriously challenged information security based on public key cryptosystems. However, to break the widely used RSA-2048 scheme, one needs millions of physical qubits, which is far beyond current technical capabilities. Here, we report a universal quantum algorithm for integer factorization by combining the classical lattice reduction with a quantum approximate optimization algorithm (QAOA). The number of qubits required is O(logN/loglog N), which is sublinear in the bit length of the integer , making it the most qubit-saving factorization algorithm to date. We demonstrate the algorithm experimentally by factoring integers up to 48 bits with 10 superconducting qubits, the largest integer factored on a quantum device. We estimate that a quantum circuit with 372 physical qubits and a depth of thousands is necessary to challenge RSA-2048 using our algorithm. Our study shows great promise in expediting the application of current noisy quantum computers, and paves the way to factor large integers of realistic cryptographic significance.
Cite
@article{arxiv.2212.12372,
title = {Factoring integers with sublinear resources on a superconducting quantum processor},
author = {Bao Yan and Ziqi Tan and Shijie Wei and Haocong Jiang and Weilong Wang and Hong Wang and Lan Luo and Qianheng Duan and Yiting Liu and Wenhao Shi and Yangyang Fei and Xiangdong Meng and Yu Han and Zheng Shan and Jiachen Chen and Xuhao Zhu and Chuanyu Zhang and Feitong Jin and Hekang Li and Chao Song and Zhen Wang and Zhi Ma and H. Wang and Gui-Lu Long},
journal= {arXiv preprint arXiv:2212.12372},
year = {2022}
}
Comments
32 pages, 12 figures