Fabrication of ultra-smooth, high-aspect ratio, sub-10 nanometer nanostructures

TL;DR

This paper introduces a versatile nanofabrication workflow that produces ultra-smooth, high-aspect ratio nanostructures below 10 nm, enabling advanced applications in photonics, electronics, and material science.

Contribution

The authors develop a novel carbon mask technique combined with focused ion beam processing to achieve deterministic, top-down nanostructuring with sub-10 nm resolution and ultra-smooth side walls.

Findings

Achieved 7 nm gap widths with 17 aspect ratio in gold nanostructures.

Fabricated dielectric resonators in resistant van der Waals materials.

Demonstrated optical responses consistent with simulations in fabricated nanoantennas.

Abstract

Deterministic and versatile approaches to sample preparation on nanoscopic scales are important in many fields including photonics, electronics, biology and material science. However, challenges exist in meeting many nanostructuring demands--particularly in emerging optical materials and component architectures. Here, we report a nanofabrication workflow that overcomes long-standing challenges in deterministic and top-down sample preparation procedures. The salient feature is a carbon mask with a low sputter yield that can be readily shaped using high resolution electron beam processing techniques. When combined with focused ion beam processing, the masking technique yields structures with ultra-smooth, near-vertical side walls. We target different material platforms to showcase the broad utility of the technique. As a first test case, we prepared nanometric gaps in evaporated Au. Gap widths of 7 plus/minus 2 nm, aspect ratios of 17, and line edge roughness values of 3sigma = 2.04 nm are achieved. Furthermore, the gap widths represent an order of magnitude improvement on system resolution limits. As a second test case, we designed and fabricated dielectric resonators in the ternary compounds MnPSe3 and NiPS3; a class of van der Waals material resistant to chemical etch approaches. Nanoantenna arrays with incrementally increasing diameter were fabricated in crystalline, exfoliated flakes. The optical response was measured by dark field spectroscopy and is in agreement with simulations. The workflow reported here leverages established techniques in material processing without the need for custom or specialized hardware. It is broadly applicable to functional materials and devices, and extends high speed focused ion beam milling to true sub-10 nm length scales.