A thulium-silicon hybrid microdisk laser

TL;DR

This paper presents a simple, silicon-compatible hybrid microdisk laser using thulium gain medium, enabling low-cost, scalable on-chip light sources at 1.9 μm for advanced optical applications.

Contribution

It introduces a straightforward, fabrication-compatible hybrid microdisk laser with thulium gain medium, compatible with standard silicon photonics foundry processes.

Findings

Operates at room temperature with standard telecom pump wavelengths.

Emits light around 1.9 μm, suitable for various optical applications.

Compatible with existing silicon photonics fabrication processes.

Abstract

Silicon photonics technology enables compact, low-power and cost-effective optical microsystems on a chip by leveraging the materials and advanced fabrication methods developed over decades for integrated silicon electronics. Silicon foundries now provide many standard building blocks required for high-performance optical circuits, including passive components such as optical waveguides, filters and (de-)multiplexors and active optoelectronic components such as high-speed modulators, switches and photodetectors. However, because silicon is a poor light emitting material, on-chip light sources are still a significant challenge for foundry offerings. Current light-source integration methods are viewed as complex, requiring incompatible and/or expensive materials and processing steps. Here we report on an ultra-compact silicon photonic laser consisting of a thulium-silicon hybrid microdisk resonator. The microdisk design is straightforward and compatible with the fabrication steps and device dimensions available in all silicon photonics foundries, whereas the gain medium is added in a backend (final step), room temperature sputter deposition. This approach allows for low-cost and high-volume wafer-scale manufacturing and co-integration of light sources with silicon passive and active devices with no adjustment to standard process flows. The hybrid laser is pumped at standard telecom wavelengths around 1.6 {\mu}m and emits around 1.9 {\mu}m, which is within an emerging spectral region of significant interest for communications, nonlinear and quantum optics, and sensing on silicon.