Chip-scale, CMOS-compatible, high energy passively Q-switched laser

TL;DR

This paper presents a CMOS-compatible, chip-scale passively Q-switched laser capable of generating high-energy pulses (>150 nJ) in a compact footprint, suitable for space and medical applications.

Contribution

The work introduces the first large mode area, passively Q-switched laser in integrated photonics with high pulse energy and efficiency in the eye-safe wavelength.

Findings

Achieved >150 nJ pulse energy on-chip

Demonstrated 40% slope efficiency

Compact footprint of ~9 mm²

Abstract

Chip-scale, high-energy optical pulse generation is becoming increasingly important as we expand activities into hard to reach areas such as space and deep ocean. Q-switching of the laser cavity is the best known technique for generating high-energy pulses, and typically such systems are in the realm of large bench-top solid-state lasers and fiber lasers, especially in the long wavelength range >1.8 um, thanks to their large energy storage capacity. However, in integrated photonics, the very property of tight mode confinement, that enables a small form factor, becomes an impediment to high energy application due to small optical mode cross-section. In this work, we demonstrate complementary metal-oxide-semiconductor (CMOS) compatible, rare-earth gain based large mode area (LMA) passively Q-switched laser in a compact footprint. We demonstrate high on-chip output pulse energy of >150 nJ in single transverse fundamental mode in the eye-safe window (1.9 um), with a slope efficiency ~ 40% in a footprint of ~9 mm2. The high energy pulse generation demonstrated in this work is comparable or in many cases exceeds Q-switched fiber lasers. This bodes well for field applications in medicine and space.