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利用微波等离子体化学气相沉积法,对单晶金刚石(100)晶面边缘进行精细切割抛光处理,形成偏离(100)晶面不同角度的倾斜面,在CH4/H2反应气体中进行同质外延生长,研究单晶金刚石边缘不同角度倾斜面对边缘金刚石外延生长的影响.实验结果表明,边缘倾斜面角度对边缘的单晶外延生长质量有影响,随着单晶金刚石边缘倾斜面角度的增大,边缘多晶金刚石数量先减少后增多,在倾斜角3.8°时边缘呈现完整的单晶外延生长特性.分析认为,边缘不同角度的倾斜面会改变周围电场强度和等离子体密度,导致到达衬底表面的含碳前驱物发生改变,倾斜面台阶表面的含碳前驱物浓度低于能形成层状台阶生长的临界浓度是减弱单晶金刚石生长过程中边缘效应的主要原因.Polycrystalline diamond is easy to appear at the edge of single crystal diamond grown by homogeneous epitaxial growth, which makes it difficult to enlarge the two-dimensional surface area of single crystal diamond. In this study, the microwave plasma chemical vapor deposition (MPCVD) is used, the edge of the single crystal diamond (100) crystal face is finely cut and polished to form an inclined surface which is different from the (100) crystal plane at different angles. After being pretreatment, homogeneous epitaxial growth is carried out in a double-substrate waveguide-type MPCVD device with CH4/H2 reaction gas. At the same time, the variation of plasma near the inclined plane of (100) crystal edge is analyzed by optical emission spectroscopy to study the effect of the tilting on the growth of the diamond edge. The experimental results show that the angle of the inclined surface of the edge has an effect on the quality of single crystal epitaxial growth of the edge. As the angle of the inclined surface of the single crystal diamond increases, the quantity of edge polycrystalline diamond first decreases and then increases. At an oblique angle of 3.8°, the edge exhibits complete single crystal epitaxial growth characteristics, which conduces to expand the surface area of single crystal diamond. According to the analysis, the inclined surface at different angle changes the surrounding electric field strength and plasma density of the edge, resulting in the change of carbon-containing precursors reaching the surface of the substrate. When the concentration of carbon-containing precursors on the inclined step surface is higher than the growth threshold of layered step, excessive carbon-containing precursors will constantly collide with each other and accumulate to form polycrystalline diamond on the step. When the concentration is lower than the growth threshold of layered step, the carbon-containing precursors on the surface of the substrate will be laid out to form a layered step. Therefore, the edge effect during the growth of single crystal diamond is weakened at the tilt angle of 3.8°, which leads the concentration of carbon-containing precursors on the inclined step surface to be lower than the growth threshold of layered step.
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Keywords:
- single crystal diamond /
- inclined surface /
- chemical vapor deposition /
- edge steps
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[2] Bray K, Kato H, Previdi R, et al. 2017 Nanoscale 10 4028
[3] Prestopino G, Marinelli M, Milani E 2017 Appl. Phys. Lett. 111 143504
[4] Chen J L, Zhang S, Cheng H J, Xu Y K 2016 The 29s Academic Exchange Meeting of the Society of Carbon Materials of the Chinese Society of Metals Shizuishan, China, October 20, 2015 p23
[5] Nad S, Gu Y, Asmussen J 2015 Diamond Relat. Mater. 60 26
[6] Kaneko J H, Fujita F, Konno Y, Gotoh T, Nishi N 2012 Diamond Relat. Mater. 26 45
[7] Lobaev M A, Gorbachev A M, Bogdanov S A 2017 EPJ Web of Conferences 149 02003
[8] Ma Z, Wu C, Wang J, Zhao H, Zhang L 2016 Diamond Relat. Mater. 66 135
[9] Tallaire A, Achard J, Silva F, Sussmann R S, Gicquel A 2004 Phys. Status Solidi 201 2419
[10] Hemley R J, Mao H K, Yan C S 2010 US Patent 7 820 131
[11] Yamada H, Chayahara A, Mokuno Y, Horino Y, Shikata S 2006 Diamond Relat. Mater. 15 1383
[12] Tomellini M, Polin R, Sessa V 1991 J. Appl. Phys. 70 7573
[13] Lee N, Badzian A 1997 Diamond Relat. Mater. 6 130
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[1] Matsumoto S, Sato Y, Kamo M, Setaka N 1982 Jpn. J. Appl. Phys. 21 183
[2] Bray K, Kato H, Previdi R, et al. 2017 Nanoscale 10 4028
[3] Prestopino G, Marinelli M, Milani E 2017 Appl. Phys. Lett. 111 143504
[4] Chen J L, Zhang S, Cheng H J, Xu Y K 2016 The 29s Academic Exchange Meeting of the Society of Carbon Materials of the Chinese Society of Metals Shizuishan, China, October 20, 2015 p23
[5] Nad S, Gu Y, Asmussen J 2015 Diamond Relat. Mater. 60 26
[6] Kaneko J H, Fujita F, Konno Y, Gotoh T, Nishi N 2012 Diamond Relat. Mater. 26 45
[7] Lobaev M A, Gorbachev A M, Bogdanov S A 2017 EPJ Web of Conferences 149 02003
[8] Ma Z, Wu C, Wang J, Zhao H, Zhang L 2016 Diamond Relat. Mater. 66 135
[9] Tallaire A, Achard J, Silva F, Sussmann R S, Gicquel A 2004 Phys. Status Solidi 201 2419
[10] Hemley R J, Mao H K, Yan C S 2010 US Patent 7 820 131
[11] Yamada H, Chayahara A, Mokuno Y, Horino Y, Shikata S 2006 Diamond Relat. Mater. 15 1383
[12] Tomellini M, Polin R, Sessa V 1991 J. Appl. Phys. 70 7573
[13] Lee N, Badzian A 1997 Diamond Relat. Mater. 6 130
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