Propagating Gottesman-Kitaev-Preskill states encoded in an optical oscillator

TL;DR

This paper demonstrates the generation and measurement of GKP qubit states in propagating light at telecommunication wavelengths, enabling scalable, room-temperature quantum computing compatible with optical fiber networks.

Contribution

It is the first to realize GKP states in propagating optical modes at telecom wavelengths and perform homodyne measurements without loss corrections.

Findings

GKP states exhibit non-classicality and non-Gaussianity at room temperature.

First demonstration of homodyne measurements on propagating GKP states without loss correction.

Compatibility of GKP states with optical fiber communication systems.

Abstract

A quantum computer with low-error, high-speed quantum operations and capability for interconnections is required for useful quantum computations. A logical qubit called Gottesman-Kitaev-Preskill (GKP) qubit in a single Bosonic harmonic oscillator is efficient for mitigating errors in a quantum computer. The particularly intriguing prospect of GKP qubits is that entangling gates as well as syndrome measurements for quantum error correction only require efficient, noise-robust linear operations. To date, however, GKP qubits have been only demonstrated at mechanical and microwave frequency in a highly nonlinear physical system. The physical platform that naturally provides the scalable linear toolbox is optics, including near-ideal loss-free beam splitters and near-unit efficiency homodyne detectors that allow to obtain the complete analog syndrome for optimized quantum error correction. Additional optical linear amplifiers and specifically designed GKP qubit states are then all that is needed for universal quantum computing. In this work, we realize a GKP state in propagating light at the telecommunication wavelength and demonstrate homodyne meausurements on the GKP states for the first time without any loss corrections. Our GKP states do not only show non-classicality and non-Gaussianity at room temperature and atmospheric pressure, but unlike the existing schemes with stationary qubits, they are realizable in a propagating wave system. This property permits large-scale quantum computation and interconnections, with strong compatibility to optical fibers and 5G telecommunication technology.