Modification of the Nanoglobular Structure of Glassy Carbon by Heat Treatment and Ion Irradiation

The results of a comparative experimental study of the structure and morphology of high-temperature glassy carbon of brand SU-2500 after high-fluence (10 18 cm –2 and higher) irradiation with 30-keV Ar + ions in the temperature range of 60–600°С and glassy carbon samples after treatment at temperatu...

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Bibliographic Details
Published in:Surface investigation, x-ray, synchrotron and neutron techniques x-ray, synchrotron and neutron techniques, 2019-09, Vol.13 (5), p.802-808
Main Authors: Andrianova, N. N., Borisov, A. M., Kazakov, V. A., Makunin, A. V., Mashkova, E. S., Ovchinnikov, M. A.
Format: Article
Language:English
Subjects:
Argon ions
Carbon
Chemistry and Materials Science
Dynamic annealing
Electron emission
Fluence
Glassy carbon
Heat treatment
High temperature
Ion irradiation
Ions
Materials Science
Morphology
Radiation damage
Raman spectra
Surface layers
Surfaces and Interfaces
Temperature
Temperature dependence
Thin Films
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Summary:The results of a comparative experimental study of the structure and morphology of high-temperature glassy carbon of brand SU-2500 after high-fluence (10 18 cm –2 and higher) irradiation with 30-keV Ar + ions in the temperature range of 60–600°С and glassy carbon samples after treatment at temperatures of 850, 1300, 2000, and 2500°С are reported and discussed. The Raman spectra of irradiated glassy carbon SU-2500 show the amorphous state of the surface layer after irradiation at temperatures below that of dynamic annealing of radiation damage, which is determined from the temperature dependence of the ion-induced electron emission yield, a graphite-like state after irradiation at temperatures of 150–250°С, and a structure typical of glassy carbon samples treated at elevated temperatures after irradiation at temperatures in the range of 250 < T ≤ 600°С. Ion irradiation under conditions of the dynamic annealing of radiation damage leads to a сellular topography, i.e., nanowalls connected by nodes. The sizes of the structure cells are about 150 and 300 nm after irradiation at temperatures of 250 and 600°С, respectively.
ISSN:1027-4510
1819-7094
DOI:10.1134/S1027451019050033