A tellurite glass optical microbubble resonator

TL;DR

This paper introduces a novel method for fabricating tellurite glass microbubble resonators with high quality factors, exploring their optical properties and potential applications in sensing and tunable lasers.

Contribution

A new CO2 laser-based fabrication process for tellurite microbubbles with high Q-factors and detailed analysis of their optical and pressure sensitivities.

Findings

Achieved quality factors up to 2.3 million.

Demonstrated temperature and pressure sensitivities of 4.9 GHz/K and 7.1 GHz/bar.

Observed single-mode lasing with a threshold of 1.66 mW.

Abstract

We present a method for making microbubble whispering gallery resonators (WGRs) from tellurite, which is a soft glass, using a CO$_2$ laser. The customized fabrication process permits us to process glasses with low melting points into microbubbles with loaded quality factors as high as $2.3 \times 10^6$. The advantage of soft glasses is that they provide a wide range of refractive index, thermo-optical and optomechanical properties. The temperature and air pressure dependent optical characteristics of both passive and active tellurite microbubbles are investigated. For passive tellurite microbubbles, the measured temperature and air pressure sensitivities are 4.9 GHz/K and 7.1 GHz/bar, respectively. The large thermal tuning rate is due to the large thermal expansion coefficient of $1.9 \times 10^{-5}$ K$^{-1}$ of the tellurite microbubble. In the active Yb$^{3+}$-Er$^{3+}$ co-doped tellurite microbubbles, C-band single-mode lasing with a threshold of 1.66 mW is observed with a 980 nm pump and a maximum wavelength tuning range of 1.53 nm is obtained. The sensitivity of the laser output frequency to pressure changes is 6.5 GHz/bar. The microbubbles fabricated by this novel method have a low eccentricity and uniform wall thickness, as determined from electron microscope images and the optical spectra. The compound glass microbubbles described herein have potential for a wide range of applications, including sensing, as tunable microcavity lasers, and for integrated photonics.