Local Surface Modification of Quartz Glass by the Laser-Induced Reactive Deposition of Carbon Clusters

Saho Osone; Makoto Hirasawa; Mikio Kumita; Hidenori Higashi; Kazuya Sawada; Kazutaka Hara; Atsushi Matsuki; Takafumi Seto; Yoshio Otani; Eiji Taguchi; Hidehiro Yasuda

doi:10.1252/jcej.16we006

Chemical Reaction Engineering

Local Surface Modification of Quartz Glass by the Laser-Induced Reactive Deposition of Carbon Clusters

Saho Osone, Makoto Hirasawa , Mikio Kumita, Hidenori Higashi, Kazuya Sawada, Kazutaka Hara, Atsushi Matsuki, Takafumi Seto, Yoshio Otani, Eiji Taguchi, Hidehiro Yasuda

Author information

Saho Osone
Faculty of Natural System, Kanazawa University
Makoto Hirasawa Corresponding author
National Institute of Advanced Industrial Science and Technology (AIST)
Mikio Kumita
Faculty of Natural System, Kanazawa University
Hidenori Higashi
Faculty of Natural System, Kanazawa University
Kazuya Sawada
Faculty of Natural System, Kanazawa University
Kazutaka Hara
Faculty of Natural System, Kanazawa University
Atsushi Matsuki
Faculty of Natural System, Kanazawa University
Takafumi Seto
Faculty of Natural System, Kanazawa University
Yoshio Otani
Faculty of Natural System, Kanazawa University
Eiji Taguchi
Research Center for Ultra-High Voltage Electron Microscopy, Osaka University
Hidehiro Yasuda
Research Center for Ultra-High Voltage Electron Microscopy, Osaka University

Keywords: Pulsed Laser Deposition, Carbon, Surface Modification, Transparent Conductive Film, Laser-Induced Phase Transition

JOURNAL RESTRICTED ACCESS

2016 Volume 49 Issue 10 Pages 920-924

DOI https://doi.org/10.1252/jcej.16we006

Details

Abstract

The surface of quartz glass was modified by the pulsed laser deposition of carbon clusters. A carbon target was irradiated by a pulsed laser transmitted through a quartz glass substrate to excite the carbon clusters deposited on the surface of the quartz. After continuous laser irradiation for several minutes, the resulting film on the irradiated spot (2 mm in diameter) was found to be optically transparent, but to exhibit electrical conductivity. The Raman spectrum of the irradiated region contained clear G and 2D band peaks, a likely sign of thin layers of graphite structures, but it also contained a D band peak originating from defects. The surface-modified regions were analyzed in detail using transmission electron microscopy and X-ray photoelectron spectroscopy. The analyses suggested that silicon carbide (SiC) generated by the laser-induced reaction between the carbon clusters and quartz substrate may have played an important role in the formation of the transparent conductive region on the surface of the quartz glass.

Corresponding author

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