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Main Authors: Hwang, Hyeon, Go, Seokjoo, Kim, Guhwan, Kim, Hong-Seok, Moon, Kiwon, Ju, Jung Jin, Lee, Hansuek, Seo, Min-Kyo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.12955
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author Hwang, Hyeon
Go, Seokjoo
Kim, Guhwan
Kim, Hong-Seok
Moon, Kiwon
Ju, Jung Jin
Lee, Hansuek
Seo, Min-Kyo
author_facet Hwang, Hyeon
Go, Seokjoo
Kim, Guhwan
Kim, Hong-Seok
Moon, Kiwon
Ju, Jung Jin
Lee, Hansuek
Seo, Min-Kyo
contents Thin-film lithium niobate (TFLN) has emerged as a powerful platform for integrated nonlinear and quantum photonics, owing to its strong optical nonlinearities, wide transparency window, and electro- and piezo-optic properties. However, conventional traveling-wave resonators, such as micro-rings, disks, and racetracks, suffer from curvature-dependent group dispersion and losses, limited spectral tunability, and parasitic nonlinearities, which constrain their performance, scalability, and operational stability in nonlinear photonic circuits. Here, we present photonic crystal (PhC) Fabry-Perot (FP) micro-resonators in TFLN that address these limitations. The device features a one-dimensional straight cavity bounded by PhC reflectors and supports well-confined standing-wave resonant modes within an engineered photonic bandgap. We achieve intrinsic quality (Q) factors of up to 1.4e6 and demonstrate that both the free spectral range (FSR) and coupling strength can be consistently controlled via cavity length and PhC coupler design, respectively. The photonic bandgap is tunable across the S-, C-, and L-bands without degradation of resonator performance. Spectral confinement of high-Q resonant modes is expected to mitigate parasitic nonlinearities, such as Raman scattering. These advances, together with the one-dimensional geometry, establish PhC FP micro-resonators as compact and scalable building blocks for high-density photonic integrated circuits targeting next-generation nonlinear and quantum applications.
format Preprint
id arxiv_https___arxiv_org_abs_2505_12955
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High-Q photonic crystal Fabry-Perot micro-resonator in thin-film lithium niobate
Hwang, Hyeon
Go, Seokjoo
Kim, Guhwan
Kim, Hong-Seok
Moon, Kiwon
Ju, Jung Jin
Lee, Hansuek
Seo, Min-Kyo
Optics
Thin-film lithium niobate (TFLN) has emerged as a powerful platform for integrated nonlinear and quantum photonics, owing to its strong optical nonlinearities, wide transparency window, and electro- and piezo-optic properties. However, conventional traveling-wave resonators, such as micro-rings, disks, and racetracks, suffer from curvature-dependent group dispersion and losses, limited spectral tunability, and parasitic nonlinearities, which constrain their performance, scalability, and operational stability in nonlinear photonic circuits. Here, we present photonic crystal (PhC) Fabry-Perot (FP) micro-resonators in TFLN that address these limitations. The device features a one-dimensional straight cavity bounded by PhC reflectors and supports well-confined standing-wave resonant modes within an engineered photonic bandgap. We achieve intrinsic quality (Q) factors of up to 1.4e6 and demonstrate that both the free spectral range (FSR) and coupling strength can be consistently controlled via cavity length and PhC coupler design, respectively. The photonic bandgap is tunable across the S-, C-, and L-bands without degradation of resonator performance. Spectral confinement of high-Q resonant modes is expected to mitigate parasitic nonlinearities, such as Raman scattering. These advances, together with the one-dimensional geometry, establish PhC FP micro-resonators as compact and scalable building blocks for high-density photonic integrated circuits targeting next-generation nonlinear and quantum applications.
title High-Q photonic crystal Fabry-Perot micro-resonator in thin-film lithium niobate
topic Optics
url https://arxiv.org/abs/2505.12955