par De Jaeger, Lisa;Vandekerckhove, Tom 
;Reep, Tom;Poelman, Stijn;Clemmen, Stéphane ;Kuyken, Bart
Référence Optics Letters, 50, 16, page (4942-4945)
Publication Publié, 2025-08-01
;Reep, Tom;Poelman, Stijn;Clemmen, Stéphane ;Kuyken, BartRéférence Optics Letters, 50, 16, page (4942-4945)
Publication Publié, 2025-08-01
Article révisé par les pairs
| Résumé : | Thin-film lithium niobate (TFLN) modulators have been pushing the limits of high-speed modulation to higher bandwidths and lower driving voltages. However, these typically occupy large footprints, limiting their integration density. For many applications, compact low-voltage modulators are desired where the bandwidth is limited by other factors, e.g., lifetimes of atomic transitions. Furthermore, integration on a CMOS-compatible platform is desirable for scaling to larger systems and to leverage existing technologies. In this work, we heterogeneously integrate a compact low-voltage lithium niobate racetrack modulator of 250 μm × 500 μm on a silicon nitride (SiN) platform. The device consists of a racetrack-shaped X-cut TFLN slab, which is micro-transfer printed onto a SiN all-pass racetrack resonator. The modulator achieves a tuning efficiency of 1.7 pmV –1 (or 3.5 pmV –1 for double-arm operation) and a Q-factor of 285,000 (with intrinsic Qi = 608,000), ensuring low operating voltages up to a measured 3-dB bandwidth of 1.18 GHz. These results pave the way toward densely integrated compact low-voltage amplitude modulators on a scalable CMOS platform. |
