Broadband, millimeter-wave anti-reflective structures on sapphire ablated with femto-second laser

TL;DR

This paper presents a novel millimeter-wave anti-reflective coating on sapphire, fabricated using femtosecond laser ablation to create sub-wavelength structures, achieving high transmission and broad bandwidth.

Contribution

It introduces a new laser ablation method to create broad-band anti-reflective structures on sapphire with high efficiency and low polarization distortion.

Findings

Achieved 97% transmission from 43 to 161 GHz.

Designed SWS with 0.54 mm pitch and 2 mm height.

Predicted RMS instrumental polarization below 0.07%.

Abstract

We designed, fabricated, and measured anti-reflection coating (ARC) on sapphire that has 116% fractional bandwidth and transmission of at least 97% in the millimeter wave band. The ARC was based on patterning pyramid-like sub-wavelength structures (SWS) using ablation with a 15 W femto-second laser operating at 1030 nm. One side of each of two discs was fabricated with SWS that had a pitch of 0.54 mm and height of 2 mm. The average ablation volume removal rate was 1.6 mm$^{3}$/min. Measurements of the two-disc sandwich show transmission higher than 97% between 43 and 161 GHz. We characterize instrumental polarization (IP) arising from differential transmission due to asymmetric SWS. We find that with proper alignment of the two disc sandwich RMS IP across the band is predicted to be 0.07% at normal incidence, and less than 0.6% at incidence angles up to 20 degrees. These results indicate that laser ablation of SWS on sapphire and on other hard materials such as alumina is an effective way to fabricate broad-band ARC.