Low Reflectance All-Glass Metasurface Lenses Based on Laser Self-generated Nanoparticles

TL;DR

This paper introduces a novel all-glass metasurface lens fabricated via laser self-organization and ion etching, achieving extremely low reflection and scalable aperture for high-power laser applications.

Contribution

It presents a new fabrication method for large-scale, durable all-glass metasurfaces with low reflectance, enabling high-power laser optics with scalable aperture and short-wavelength operation.

Findings

Achieved broadband reflection below 0.15% at 532 nm.

Demonstrated fabrication of 1 mm diameter optical elements.

Enabled patterning and phase control for high-power laser applications.

Abstract

Optical metasurfaces, comprised of subwavelength nanostructures, hold a great promise to high-power laser optics but also a limited pertinence due to their currently limited aperture size, throughput and durability. Here, an alternative approach is presented, reliant on laser-controlled self-organizing mask formation followed by ion etching which results in an all-fused-silica-glass metasurface. Two 1 mm diameter optical elements (an axicon lens and a shadower) are fabricated and their optical performance is validated at 532 nm wavelength with an extremely low broadband reflection (<0.15%) - a result of the unique metasurface elements shape. The self-organizing working principle enables producing large amounts of nano-elements at-once, thus a path for aperture scaleup. It also enables generation of sub-100 nm nanoelements, thus a path to short wavelengths operation. Two key advancements towards viability are presented: a laser scan with in-situ transmission feedback enables patterning the etching mask to a prescribed nanoparticle distribution, and a crafted beyond-mask-erosion-point etching of the mask enables increasing the metasurface phase difference to at least pi, while keeping extremely low reflection across it. This paves a path to high-power lasers optics, requiring large aperture, high throughput and laser light durability.