Direct laser writing of high aspect ratio nanochannels for nanofluidics

TL;DR

This paper presents a novel direct laser writing technique to fabricate high aspect ratio nanochannels in diamond and glass, enabling optically accessible and mechanically stable nanofluidic devices for advanced applications.

Contribution

It introduces a new method for creating high aspect ratio nanochannels with rectangular cross-sections using laser-induced transformation and delamination processes.

Findings

Nanochannels with aspect ratios over fifty were successfully fabricated.

Channels are water-filling, resistant to clogging, and mechanically stable.

Reflectance of nanochannels can be measured via microspectrophotometry.

Abstract

Nanochannels with high width-to-height aspect ratios are desirable for many applications, particularly those requiring optical access, but remain challenging to fabricate. In this work, the direct laser writing of such channels between diamond films and glass substrates is introduced. As previously reported, laser light can transform a portion of diamond film into a nanostrip. The strip induces delamination of the surrounding film, causing the formation of two nanochannels with triangular cross-sections. Here, it is demonstrated that nanochannels with rectangular cross-sections and width-to-height aspect ratios exceeding fifty can form between pairs of nanostrips. With atomic force microscopy, the maximum strip spacing that produces these nanochannels is investigated, and it is demonstrated that the reflectance of the channels can be measured by microspectrophotometry. The microstructure of the nanochannels, including nanostrips, and processes that occur during laser writing are inferred from transmission electron microscopy and electron energy loss spectroscopy. By fabricating a nanofluidic device and using microspectrophotometry, it is found that the nanochannels fill with water through capillary action, are resistant to clogging, and are mechanically stable against water filling. A versatile platform for producing high-aspect-ratio nanochannels that are optically accessible and fluidically functional is presented, thereby expanding opportunities for advanced applications.