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Experimental quantum simulation of a topologically protected Hadamard gate via braiding Fibonacci anyons

Authors :
Yu-ang Fan
Yingcheng Li
Yuting Hu
Yishan Li
Xinyue Long
Hongfeng Liu
Xiaodong Yang
Xinfang Nie
Jun Li
Tao Xin
Dawei Lu
Yidun Wan
Source :
The Innovation, Vol 4, Iss 5, Pp 100480- (2023)
Publication Year :
2023
Publisher :
Elsevier, 2023.

Abstract

Topological quantum computation (TQC) is one of the most striking architectures that can realize fault-tolerant quantum computers. In TQC, the logical space and the quantum gates are topologically protected, i.e., robust against local disturbances. The topological protection, however, requires complicated lattice models and hard-to-manipulate dynamics; even the simplest system that can realize universal TQC—the Fibonacci anyon system—lacks a physical realization, let alone braiding the non-Abelian anyons. Here, we propose a disk model that can simulate the Fibonacci anyon system and construct the topologically protected logical spaces with the Fibonacci anyons. Via braiding the Fibonacci anyons, we can implement universal quantum gates on the logical space. Our disk model merely requires two physical qubits to realize three Fibonacci anyons at the boundary. By 15 sequential braiding operations, we construct a topologically protected Hadamard gate, which is to date the least-resource requirement for TQC. To showcase, we implement a topological Hadamard gate with two nuclear spin qubits, which reaches 97.18% fidelity by randomized benchmarking. We further prove by experiment that the logical space and Hadamard gate are topologically protected: local disturbances due to thermal fluctuations result in a global phase only. As a platform-independent proposal, our work is a proof of principle of TQC and paves the way toward fault-tolerant quantum computation.

Subjects

Subjects :
Science (General)
Q1-390

Details

Language :
English
ISSN :
26666758
Volume :
4
Issue :
5
Database :
Directory of Open Access Journals
Journal :
The Innovation
Publication Type :
Academic Journal
Accession number :
edsdoj.fcd2266fbd2413fab47be32323e4f13
Document Type :
article
Full Text :
https://doi.org/10.1016/j.xinn.2023.100480