# Scalable, green fabrication of single-crystal noble metal films and   nanostructures for low-loss nanotechnology applications

**Authors:** Sasan V. Grayli, Xin Zhang, Finlay C. MacNab, Saeid Kamal, Gary W., Leach

arXiv: 1906.07879 · 2019-06-20

## TL;DR

This paper presents a scalable, eco-friendly wet chemical method for fabricating high-quality, single-crystal noble metal films and nanostructures, advancing low-loss nanotechnology applications.

## Contribution

It introduces a novel green fabrication technique for monocrystalline noble metals, enabling high-quality nanostructures with improved optical and electrical properties.

## Key findings

- Ultrasmooth, epitaxial single-crystal films achieved
- Enhanced pattern transfer and feature quality
- Reduced optical and resistive losses

## Abstract

High quality metal thin films and nanostructures are critical building blocks for next generation nanotechnologies. They comprise low-loss circuit elements in nanodevices, provide new catalytic pathways for water splitting and $CO_2$ reduction technologies, and enable the confinement of spatially extended electromagnetic waves to be harnessed for application in information processing, energy harvesting, engineered metamaterials, and new technologies that will operate in the quantum plasmonics limit. However, the controlled fabrication of high-definition single-crystal subwavelength metal nanostructures remains a significant hurdle, due to the tendency for polycrystalline metal growth using conventional physical vapor deposition methods, and the challenges associated with placing solution-grown nanocrystals in desired orientations and locations on a surface to fabricate functional devices. Here, we introduce a new scalable, green, wet chemical approach to monocrystalline noble metals that enables the fabrication of ultrasmooth, epitaxial, single-crystal films of controllable thickness. They are ideal for the subtractive manufacture of nanostructure through ion beam milling, and additive crystalline nanostructure via lithographic patterning to enable large area, single-crystal metamaterials and high aspect ratio nanowires. Our single-crystal nanostructures demonstrate improved feature quality and pattern transfer yield, reduced optical and resistive losses, tailored local fields, and greatly improved stability compared to polycrystalline structures, supporting greater local field enhancements and enabling new practical advances at the nanoscale.

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Source: https://tomesphere.com/paper/1906.07879