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| 研究生: |
廖俊傑 Jyun-jie Liao |
|---|---|
| 論文名稱: |
不同能量的Ar+與N2+離子束轟擊GaAs(100)表面的光輻射現象 Light emission from a GaAs(100) target during several keV Ar+ and N2+ ions sputtering |
| 指導教授: |
李敬萱
Chin-Shuang Lee |
| 口試委員: | |
| 學位類別: |
碩士 Master |
| 系所名稱: |
工學院 - 材料科學與工程研究所 Graduate Institute of Materials Science & Engineering |
| 畢業學年度: | 97 |
| 語文別: | 中文 |
| 論文頁數: | 48 |
| 中文關鍵詞: | 砷化鎵 、光輻射 、濺射 |
| 外文關鍵詞: | light emission, sputtering, gallium arsenide |
| 相關次數: | 點閱:13 下載:0 |
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由於一加速離子射束與固體表面碰撞時產生的受激粒子,會經由非輻射降激 (radiationless deexcitation) 或輻射降激釋放出光子的方式回到穩定態,以9keV, 6keV, 3keV的Ar+離子束及N2+離子束轟擊乾淨GaAs(100)表面時,我們可探討入射離子能量及種類與GaI三條原子光譜線GaI417.2nm, GaI403.3nm, GaI294.4nm輻射強度的關係;另外研究報告指出,不論是輻射降激或非輻射降激過程都與表面的化學狀態有很密切的關係,例如有氧氣分子的存在會增強鋁靶在離子轟打下光輻射的強度,實驗中分別以9keV Ar+離子束及9keV N2+離子束轟擊GaAs(100)表面,觀察GaI的三條原子光譜線輻射強度在腔體含有不同壓力的氧氣或氮氣下的變化,並計算氧的附著率及氧的濺射率。
The interaction of energetic ions with solid surfaces results in the emission of excited ions. The excited particles decay either by a radiationless deexcitation process or by radiative photon emission. In this study, we use 9keV, 6keV and 3keV Ar+ ions and N2+ ions bombard clean GaAs(100) target separately. Results of the measurements on the projectile energy and ion type dependences of Ga I 417.2nm, 403.3nm and 294.4nm lines are presented. It is known that the process of radiationless and radiative deexcitation are highly sensitive to the chemical state of the surface. For example, the presence of oxygen has been found to enhance the light emission from aluminium target under ion impact. In this study, we use 9keV Ar+ ions and N2+ ions bombard GaAs(100) to measure the light intensities are as a function of O2 or N2 pressure. Also, the oxygen sputtering coefficient So and oxygen sticking probability Cs are studied.
[1] Secondary Ion Mass Spectrometry (eds. A. Benninghoven, F. G. Rudenauer and H. W. Wernear;Springer-Velog Berlin Heidelberg New York 1987) chap 2.
[2] Sputtering by Particle Bombardment III (eds. R. Behrisch and K. Wittmaack;Springer-Verlog Berlin Heidelberg New York 1991) p.1~11.
[3] G. E. Thomas, Surface Science, 90, 381 (1979).
[4] P. Sigmund, Physical Review, 184, 383 (1969);187, 768 (1969).
[5] C. W. White, Nuclear Instruments and Methods, 149 ,497 (1978) .
[6] N. H. Tolk, D. L. Simms, E. B. Foley and C. W. White, Radiation Effects, 18,221 (1973) .
[7] P. Sigmund, Inelastic Ion-Surface Collision (eds. N. H. Tolk, J. C. Tully, W. Heiland and C. W. White;Academic Press, Inc. New York San Francisco London 1977) p.121.
[8] H. G. Prival, Surface Science, 16, 443 (1978) .
[9] I. S. T. Tsong, Inelastic Particle-Surface Collision (eds. E. Taglauer and W. Heiland;Springer-Verlog Berlin Heidelberg New York 1981) p.258.
[10] R. B. Wright and D. M. Gruen, J. Chem. Phys., 73, 664 (1980).
[11] R. Kelly, Inelastic Particle-Surface Collision (eds. E. Taglauer and W. Heiland;Springer-Verlog Berlin Heidelberg New York 1981) p.292.
[12] R. S. Bhattacharya, J. F. Van der Veen, C. B. W. Kerkdijk, and F. W. Saris, Radiat. Eff. 32, 25 (1977)
[13] D. Ghose, Vacuum, 46, 13 (1995).
[14] D. Ghose, U. Brinkmann and R. Hippler, Surface Science, 327, 53 (1995).
