| 光谱学与光谱分析 |
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| Raman Spectra Study on the Structure and Thermal Stability of Vacuum Annealed Cr-DLC Films Prepared with UBMS |
| LU Bao-qi, XU Yao-xian, SHEN Guang-yao, JI Jiang-hua, WANG Lin-jun |
| School of Materials Science and Engineering, Shanghai University, Shanghai 200444 China |
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Abstract Chromium doped amorphous hydrogenated carbon a-C∶H(Cr) films (2.23 μm in thickness)have been successfully prepared with unbalanced magnetron sputtering technology(UBMS) in this paper. Raman spectrum and X-ray photoelectron spectroscopy (XPS) have been used to study the structure and thermal stability of the Chromium doped diamond-like carbon films (Cr-DLC). The results indicate that, at the room temperature, the Raman absorption peak “G” near 1 580 cm-1was assigned to C—C stretching vibration mode (E2g) in the Cr-DLC films, while the peak “D” near 1 350 cm-1was assigned to sp2 breathing vibration mode (A1g). The relative concentration of sp3 bond in the film is at 48%. When heated till 300 ℃, the Raman pattern of sample is similar to that of the sample at room temperature, indicating the structure of Cr-DLC film is stable. At 400 ℃, the ratio of ID/IG and the concentration of sp2 bond clearly increase, indicating the change of the structure in the Cr-DLC and the appearance of graphitization. With temperature going up, the rise of ID/IG ratio and the shift of the peak “G” to high wavenumber show that the rise of sp2/sp3 ratio, the intensity of graphitization, and the decline of the disorder of sp2 in the Cr-DLC films lead to the increase of the friction coefficient and wearing rate and the decline of the Cr-DLC thermal stability. When the it is up to 600 ℃, the ratio of ID/IG and the concentration of sp2 bond reach the max value while the Cr-DLC film loses its efficacy.
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Received: 2015-08-28
Accepted: 2015-12-19
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Corresponding Authors:
LU Bao-qi
E-mail: lbqi_1@shu.edu.cn
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[1] Chowdhury S, Laugier M T, Rahman I Z. Thin Solid Films, 2004, 447-448: 174.
[2] Dillon R O, Woollam J A. Physical Review, 1984, B29: 3482.
[3] JU Jian-hua, XIA Yi-ben, ZHANG Wei-li(居建华,夏义本,张伟丽). Journal of Functional Materials(功能材料), 2001, 32(5): 473.
[4] Mariotto G, Freire JrF L, Achete C A. Thin Solid Films, 1994, 241: 255.
[5] Farrow L A, Willkens B J, Gozdz A S, et al. Physical Review, 1990, B41: 10132.
[6] Gonzalez-Hernandez J, Gozdz B S, Pawlik D A. Material Science Forum., 1989, 52-53: 543.
[7] Bharathy P V, Nataraj D, Chu P K, et al. Applied Surface Science, 2010, 257: 143.
[8] Dai W, Wang A Y. J. Journal of Alloys and Compounds, 2011, 509: 4626.
[9] Ferrari A C, J. Robertson J I. Physieal Review. B. Condensed Matter, 2000, 61(20): 14095.
[10] Baptista D L,Zawislak F C. Diamond and Related Materials,2004, 13(10); 1791. |
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