Fiber transmission of cluster states via multi-level time-bin encoding

TL;DR

This paper demonstrates the first successful transmission of a four-qubit cluster state over 25 km of optical fiber using multi-level time-bin encoding, advancing quantum communication capabilities.

Contribution

It introduces a novel multi-level time-bin encoding method for transmitting cluster states over fiber, eliminating the need for resource-intensive gates and enabling long-distance quantum networking.

Findings

Successfully transmitted a four-qubit cluster state over 25 km fiber

Implemented time-bin beam splitter for projective measurements

Certified genuine multipartite entanglement and demonstrated quantum computing operations

Abstract

The next generation of telecommunication networks will rely on the transmission of complex quantum states to enable secure and transformative information processing, utilizing entanglement and superposition. Cluster states - multipartite entangled states that retain entanglement under local measurements - are a vital resource for quantum networking applications such as blind photonic quantum computing, quantum state teleportation and all-photonic quantum repeaters. However, the transmission of cluster states over optical fiber has remained elusive with previous approaches. Here, we demonstrate the first transmission of a four-qubit cluster state over 25 km of single-mode fiber by using a two-photon multi-level time-bin encoding. We directly generate the state by exploiting coherent control of a parametric generation process, rendering a resource-intensive controlled-phase gate obsolete. To enable efficient and reconfigurable projective measurements on the multi-level time-bin encoded state, we introduce chirped-pulse modulation and implement the first time-bin beam splitter, allowing us to certify genuine multipartite entanglement and to demonstrate one-way computing operations. Our approach enables the transmission of complex quantum states over long-distance fibers, permitting the implementation of multipartite protocols and laying the foundation for large-scale quantum resource networks.