Nonlinear Electro-Optic Visible Photonic Circuits for Solid-State Quantum Defects
Abstract
Integrated visible photonic engines for solid-state quantum defects provide a foundation for scalable quantum networks. While miniaturization is advancing, active manipulation remains limited by the difficulty of achieving simultaneous milliwatt-scale visible light generation and high-contrast modulation. Despite extensive efforts, the concurrent chip-scale realization of nonlinear frequency conversion and fast temporal gating for high-fidelity quantum control has remained elusive. Here, we demonstrate a monolithic thin-film lithium niobate (TFLN) platform integrating periodically poled frequency conversion with GHz-bandwidth electro-optic (EO) switching. The device delivers off-chip green-light power exceeding 1 mW with an extinction ratio (ER) of 42.2 dB, enabling coherent spin control and time-resolved lifetime measurements of individual nitrogen-vacancy (NV) centers in diamond through nanosecond gating. System performance is validated through pulsed optically detected magnetic resonance (ODMR), Rabi oscillations, and Ramsey interference, supported by time-tagged photon counting with nanosecond resolution. By unifying sufficient nonlinear light generation with high-speed active manipulation, this platform establishes a scalable framework for the realization of high-rate quantum communication nodes.
Cite
@article{arxiv.2603.21751,
title = {Nonlinear Electro-Optic Visible Photonic Circuits for Solid-State Quantum Defects},
author = {Yongchan Park and Yong Soo Lee and Hansol Kim and Jaepil Park and Junhyung Lee and Hye-yoon Jeon and Jinil Lee and Yong-gwon Kim and Yeeun Choi and Min-Kyo Seo and Dae-Hwan Ahn and Hojoong Jung and Dongyeon Daniel Kang and Hyounghan Kwon},
journal= {arXiv preprint arXiv:2603.21751},
year = {2026}
}