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Silicon carbide: A promising platform for scalable quantum networks

Yu Zhou, Junhua Tan, Haojun Hu, Sikai Hua, Chunhui Jiang, Bo Liang, Tongyuan Bao, Xinfang Nie, Shumin Xiao, Dawei Lu, Junfeng Wang, Qinghai Song

2025Applied Physics Reviews13 citationsDOI

Abstract

Quantum networks based on solid-state spin defects present a transformative approach to secure communication and distributed quantum computing, utilizing quantum entanglement and coherent spin–photon interfaces. Silicon carbide (SiC) stands out as a compelling material platform due to its unique combination of a wide bandgap, high optical nonlinearity, CMOS-compatible fabrication, and controllable spin-active defects. These intrinsic properties facilitate efficient photon emission, robust spin coherence at both room and cryogenic temperatures, and integration with photonic nanostructures. Recent advancements in defect engineering and micro-nanophotonics have unlocked the potential of SiC quantum nodes, which feature electron-nuclear spin systems for high-fidelity quantum operations and long-lived quantum memories. Key steps such as single-shot readout and spin-photon entanglement have been successfully demonstrated, bringing SiC closer to a real quantum network platform. This review offers a comprehensive overview of the advancements in SiC-based quantum networks, encompassing key aspects such as defect fabrication methodologies, optimization of spin-photon interfaces, and strategies for photonic integration. Additionally, it examines the existing challenges and outlines promising future directions in this rapidly evolving field.

Topics & Concepts

ScalabilitySilicon carbideQuantumComputer scienceNanotechnologyMaterials sciencePhysicsDatabaseMetallurgyQuantum mechanicsQuantum Information and CryptographyQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomena
Silicon carbide: A promising platform for scalable quantum networks | Litcius