Litcius/Paper detail

Photonics-integrated terahertz transmission lines

Yazan Lampert, Amirhassan Shams‐Ansari, Aleksei Gaier, Alessandro Tomasino, Xuhui Cao, Letícia Magalhães, Shima Rajabali, Marko Lončar, Ileana-Cristina Benea-Chelmus

2025Nature Communications21 citationsDOIOpen Access PDF

Abstract

Modern communication and sensing technologies connect the optical domain with the microwave domain. Accessing the terahertz region from 100 GHz to 10 THz is critical for providing larger bandwidths capabilities. Despite progress in integrated electronics, they lack a direct link to the optical domain, and face challenges with increasing frequencies ( > 1 THz). Electro-optic effects offer promising capabilities but are currently limited to bulk nonlinear crystals, missing out miniaturization, or to sub-terahertz bandwidths. Here, we address these challenges by realizing photonic circuits that integrate terahertz transmission lines on thin-film lithium niobate (TFLN). By providing terahertz field confinement and phase-matched interaction with optical fields, our miniaturized devices support low-noise and broad bandwidth terahertz generation and detection spanning four octaves (200 GHz to > 3 THz). By leveraging photonics' advantages in low-loss and high-speed control, our platform achieves control over the terahertz spectrum and its amplitude, paving the way for compact and power-efficient devices with applications in telecommunications, spectroscopy, quantum electrodynamics and computing.

Topics & Concepts

Terahertz radiationTerahertz gapPhotonicsLithium niobateOptoelectronicsMiniaturizationTerahertz spectroscopy and technologyBandwidth (computing)PhotomixingTerahertz time-domain spectroscopyElectronic circuitTransmission (telecommunications)ElectronicsComputer scienceMaterials sciencePhysicsTelecommunicationsOpticsElectrical engineeringNanotechnologyFar-infrared laserEngineeringTerahertz metamaterialsLaserTerahertz technology and applicationsPhotonic and Optical DevicesPhotonic Crystals and Applications