A hybrid integrated dual-microcomb source

TL;DR

This paper introduces a fully integrated, electrically driven dual-microcomb source using commercial components, enabling compact, efficient, and turnkey dual-comb systems suitable for diverse high-precision applications.

Contribution

It presents the first fully integrated, power-efficient dual-microcomb source with commercial components, relaxing spectral purity requirements and demonstrating wide-band RF spectrum conversion.

Findings

Achieved pump-to-comb sideband efficiency of up to 40% at mW power levels

Demonstrated down-conversion of optical spectrum to RF domain from 1400 nm to 1700 nm

Enabled resilient soliton microcombs with thermal drift tolerance

Abstract

Dual-comb interferometry is based on self-heterodyning two optical frequency combs, with corresponding mapping of the optical spectrum into the radio-frequency domain. The dual-comb enables diverse applications, including metrology, fast high-precision spectroscopy with high signal-to-noise ratio, distance ranging, and coherent optical communications. However, current dual-frequency-comb systems are designed for research applications and typically rely on scientific equipment and bulky mode-locked lasers. Here we demonstrate for the first time a fully integrated power-efficient dual-microcomb source that is electrically driven and allows turnkey operation. Our implementation uses commercially available components, including distributed-feedback and Fabry--Perot laser diodes, and silicon nitride photonic circuits with microresonators fabricated in commercial multi-project wafer runs. Our devices are therefore unique in terms of size, weight, power consumption, and cost. Laser-diode self-injection locking relaxes the requirements on microresonator spectral purity and Q-factor, so that we can generate soliton microcombs resilient to thermal frequency drift and with pump-to-comb sideband efficiency of up to 40\% at mW power levels. We demonstrate down-conversion of the optical spectrum from 1400 nm to 1700 nm into the radio-frequency domain, which is valuable for fast wide-band Fourier spectroscopy, which was previously not available with chip-scale devices. Our findings pave the way for further integration of miniature microcomb-based sensors and devices for high-volume applications, thus opening up the prospect of innovative products that redefine the market of industrial and consumer mobile and wearable devices and sensors.