Ultrafast laser inscribed waveguides in tailored fluoride glasses: An enabling technology for mid-infrared integrated photonics devices

TL;DR

This paper demonstrates ultrafast laser inscription of high index-contrast, low-loss waveguides in hybrid fluoride glasses, enabling advanced mid-infrared integrated photonics devices with potential for fiber integration.

Contribution

It introduces a novel laser inscription technique in hybrid zirconium/hafnium fluoride glasses, achieving significant positive index change and supporting well-confined mid-infrared waveguides.

Findings

Positive index change of nearly 10$^{-2}$ in hybrid glasses

Fabrication of high NA waveguides at 3.1 μm wavelength

Waveguides support mode-field diameters as small as 12 μm

Abstract

Zirconium fluoride (ZBLAN) glass, the standard material used in fiber-based mid-infrared photonics, has been re-designed to enable the fabrication of high index-contrast low-loss waveguides via femtosecond laser direct writing. We demonstrate that in contrast to pure ZBLAN, a positive index change of close to 10$^{-2}$ can be induced in hybrid zirconium/hafnium (Z/HBLAN) glasses during ultrafast laser inscription and show that this can be explained by an electron cloud distortion effect that is driven by the existence of two glass formers with contrasting polarizability. High numerical aperture (NA) type-I waveguides that support a well confined 3.1 $\mu$m wavelength mode with a mode-field diameter (MFD) as small as 12 $\mu$m have successfully been fabricated. These findings open the door for the fabrication of mid-infrared integrated photonic devices that can readily be pigtailed to existing ZBLAN fibers.