Comparison of different atmospheric-pressure plasma sources for controlled decomposition of organic thin-films

Warning

This publication doesn't include Institute of Computer Science. It includes Faculty of Science. Official publication website can be found on muni.cz.
Authors

SIHELNÍK Slavomír BEIER Oliver JAMAATI KENARI Ali XU Jun SEEMANN Thomas KRETZSCHMAR Bjoern PFUCH Andreas SPANGE Sebastian KRUMPOLEC Richard KOVÁČIK Dušan

Year of publication 2022
Type Conference abstract
MU Faculty or unit

Faculty of Science

Citation
Description Nanostructured materials are attractive for applications in many industries that demand low-cost manufacturing. Thin-films based on organics are easy to process thanks to their solubility and flexibility, which is advantageous for implementation into mass production. Nowadays, thin organic-based films are successfully used in optical and electronic devices that are made via two basic approaches: bottom-up and top-down. The present study compares various nonthermal plasma sources as tools for removal of organic layers in the scope of top-down methods. Atmospheric-pressure plasma etching is proposed here as a dry, efficient and controllable method for decomposition of organic nanolayers with respect to their thickness without affecting the substrate material. The selection of applied plasma sources is based on different geometry, power input or working and surrounding gas, with respect to areal uniformity and thermal sensitivity of organic coatings. Stearic acid (SA) layers were evaporated on soda-lime glass substrates. Initial layer thickness of 70 nm was evaluated using confocal profilometry. Water contact angle measurements (WCA) of plasma-activated glass were carried out to optimize plasma parameters suitable for efficient decomposition. FTIR analysis was used for detection of SA layer decomposition after plasma exposure. XPS was carried out to reveal the chemical nature of parallel mechanisms involved in plasma-glass interaction. The impact of the tested plasmas on the morphology of soda-lime glass substrate was analysed using AFM.
Related projects:

You are running an old browser version. We recommend updating your browser to its latest version.

More info