Monolithic lithium niobate photonic chip for efficient terahertz-optic modulation and terahertz generation

TL;DR

This paper presents a monolithic lithium niobate photonic chip that enables efficient bidirectional THz-optic interaction, achieving high-speed modulation and generation up to 500 GHz, advancing integrated THz photonics.

Contribution

The work introduces a monolithic integrated lithium niobate chip supporting efficient THz-optic modulation and generation, with significant improvements in power efficiency and frequency performance.

Findings

THz-optic modulator with 8V RF half-wave voltage at 500 GHz

Continuous wave THz generation efficiency of 4.8×10^-6 /W at 500 GHz

High-speed electro-THz modulation up to 35 GHz

Abstract

The terahertz (THz) frequency range, bridging the gap between microwave and infrared frequencies, presents unparalleled opportunities for advanced imaging, sensing, communications, and spectroscopy applications. Terahertz photonics, in analogy with microwave photonics, is a promising solution to address the critical challenges in THz technologies through optical methods. Despite its vast potential, key technical challenges remain in effectively interfacing THz signals with the optical domain, especially THz-optic modulation and optical generation of THz waves. Here, we address these challenges using a monolithic integrated photonic chip designed to support efficient bidirectional interaction between THz and optical waves. Leveraging the significant second-order optical nonlinearity and strong optical and THz confinement in a thin-film lithium niobate on quartz platform, the chip supports both efficient THz-optic modulation and continuous THz wave generation at up to 500 GHz. The THz-optic modulator features a radio frequency (RF) half-wave voltage of 8V at 500 GHz, representing more than an order of magnitude reduction in modulation power consumption from previous works. The measured continuous wave THz generation efficiency of 4.8*10-6 /W at 500 GHz also marks a tenfold improvement over existing tunable THz generation devices based on lithium niobate. We further leverage the coherent nature of the optical THz generation process and mature optical modulation techniques to realize high-speed electro-THz modulation at frequencies up to 35 GHz. The chip-scale THz-photonic platform paves the way for more compact, efficient, and cost-effective THz systems with potential applications in THz communications, remote sensing, and spectroscopy.