PTFE-Doped CeO2 Films: Synthesis, Characterization and Properties

Y.  Taga; K.   Nishimura; Y.  Hisamatsu

doi:10.6000/2369-3355.2019.06.02.1

Authors

Y. Taga Thin-film Research Center, Chubu University, Kasugai, Japan
K. Nishimura Thin-film Research Center, Chubu University, Kasugai, Japan
Y. Hisamatsu Thin-film Research Center, Chubu University, Kasugai, Japan

DOI:

https://doi.org/10.6000/2369-3355.2019.06.02.1

Keywords:

Hybrid sputtering films, CeO2-PTFE film, Super-hard, UV shieldinng, Water repellamt, Bending rsistance, Transparent in visible light, PTFE doping, XPS, Nanoindentor.

Abstract

Multi-functional hybrid films were developed by doping PTFE into CeO₂by co-sputtering of CeO₂and PTFE targets. The hybrid films formed on borosilicate glass substrate containing from 5 to 15 vol. % PTFE in CeO₂showed UV shielding, high indentation hardness, hydrophobicity, optical transmittance in visible light, and high bending crack resistance. Optical properties of 100 nm thick CeO₂-5 vol. % PTFE film revealed UV light shielding of more than 80 % at 380 nm and visible light transmittance higher than 80 %. Indentation hardness measured under the load of 0.001mN was more than 16,000N/mm² of 2.7 times higher than the glass substrate. No crack in the film was observed by bending 1.5 cm in diameter. Furthermore, the hydrophobic surface property was evaluated by the water contact angle to be higher than 90 degrees. Preliminary characterization of the CeO₂-PTFE film using XPS and XMA revealed that chemical states of F in sputter doped PTFE in CeO₂ can be considered to exist as C-F and Ce-F compounds. On the other hand, chemical states of Ce changed partially from Ce⁺⁴(CeO₂) to Ce⁺³ (Ce₂O₃ or CeF₃) with increasing doped PTFEF in the film.

In this rapid communication, we preliminary described the optical, mechanical and chemical properties of newly developed hybrid CeO₂-PTFE films prepared by sputtering.

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