Communications Physics (Jun 2024)

Reconfigurable synthetic dimension frequency lattices in an integrated lithium niobate ring cavity

  • Hiep X. Dinh,
  • Armandas Balčytis,
  • Tomoki Ozawa,
  • Yasutomo Ota,
  • Guanghui Ren,
  • Toshihiko Baba,
  • Satoshi Iwamoto,
  • Arnan Mitchell,
  • Thach G. Nguyen

DOI
https://doi.org/10.1038/s42005-024-01676-9
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 9

Abstract

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Abstract Harnessing non-spatial properties of photons as if they represent an additional independent coordinate underpins the emerging synthetic dimension approach. It enables probing of higher-dimensional physical models within low-dimensional devices, such as on a planar chip where this method is relatively nascent. We demonstrate an integrated thin-film lithium niobate ring resonator that, under dynamic modulation, simulates a tight-binding model with its discrete frequency modes representing lattice sites. Inter-mode coupling, and the simulated lattice geometry, can be reconfigured by controlling the modulating signals. Up to a quasi-3D lattice connectivity with controllable gauge potentials has been achieved by simultaneous synchronized nearest-, second- and third-nearest-neighbor coupling, and verified by acquiring synthetic band structures. Development of synthetic frequency dimension devices in the thin-film lithium niobate photonic integration platform is a key step in increasing the complexity of topological models achievable on a chip, combining efficient electro-optic mode coupling with non-linear effects for long-range mode interactions.