丙酮环境下ECR微波等离子体辅助化学气相沉积类金刚石薄膜研究

利用电子回旋共振（ECR）微波等离子体辅助化学气相沉积技术、工作气氛为丙酮，在光学玻璃衬底上得到了光滑、致密、均匀的类金刚石薄膜.在工艺研究中，对等离子体中氧的存在及其作用进行了分析.原子力显微镜分析表明，薄膜的表面粗糙度小于10nm，晶粒 尺寸约为100nm.拉曼光谱和中红吸收谱研究发现，薄膜具有强烈的荧光效应，含有sp1，sp2，sp3杂化C—C，sp3杂化CH3，羰基CO、含氧多元 环以及—COOH基等.利用纳米力学探针以 及近红区红外透射谱分析了薄膜的力学及光学性能，结果表明，薄膜的显微硬度接近4 关键词： 类金刚石薄膜 ECR微波等离子体 丙酮气氛 红外光谱     

织构金刚石薄膜的成核与生长

在加衬底偏压和不加衬底偏压两种情况下，用微波等离子体化学汽相沉积（MWCVD）技术在Ｓｉ（１００）衬底上合成了织构的金刚石薄膜使用扫描电子显微镜（ＳＥＭ）和取向Ｘ射线衍射技术证实了我们得到的样品是织构的金刚石薄膜观察了织构的金刚石薄膜的成核和生长过程，从理论上对金刚石薄膜异质外延的成核和生长机理进行了探讨 关键词：     

金刚石薄膜的蓝光发射

利用氮化铝陶瓷作为衬底，在不同甲烷与氢气的配比流量下，利用热丝ＣＶＤ方法制备了一个系列的金刚石薄膜，通过测量样品在４３０ｎｍ处的光致荧光（ＰＬ）谱及其Ｒａｍａｎ光谱，给出了金刚石薄膜的结构与生长信息，薄膜ＰＬ强度随甲烷浓度增加到３％时达到最大，继续增加了甲烷浓度ＰＬ强度下降。     

ECR-PECVD制备SiO2薄膜中衬底射频偏压的作用

采用微波电子回旋共振等离子体增强化学气相沉积（ECR－PECVD）技术在单晶衬底上制备了SiO2薄膜,研究了射频偏压对薄膜特性的影响。通过X射线光电子能谱（XPS）、傅里叶变换红外线光谱（FTIR）、原子力显镜（AFM）和扫描隧道显微镜（STM）三维形貌图测量等手段,对成膜特性进行了分析。实验结果表明,通过改变射频偏压的参数来控制离子轰击能量,对ECR－PECVD成膜的内应力、溅射现象、微观结构和化学计量均有明显的影响。     

直流等离子体CVD法合成的金刚石膜的断裂强度研究

研究了直流等离子体激光化学汽相沉积（ＣＶＤ）法合成金刚石膜的断裂强度。利用压力爆破技术测量了圆形金刚石膜的断裂强度。实验结果表明，断裂强度与金刚石颗粒大小、膜厚度、圆半径、甲烷浓度及衬底温度有密切的依赖关系，并对这些结果进行了讨论。 关键词：     

富勒烯作为过渡层生长金刚石薄膜研究

采用微波等离子体化学气相淀积法，以Ｃ６０膜过渡层，在光滑的单晶Ｓｉ衬底（１００）表面的研磨的石英衬底表面等光学衬底上，首次在无衬底负偏压条件下生长出多晶金刚石薄膜，通过扫描电镜观察到生长膜晶粒呈莱花状，生长表面为金刚石（１００）界面。     

生长条件和退火对金刚石薄膜光学性质的影响

提出一种分析微波等离子体化学气相沉积工艺条件对金刚石薄膜的组成和光学性质影响的方法。采用红外椭圆偏振光谱仪来分析Si衬底上金刚石薄膜的组成和光学性质，研究微波等离子体化学气相沉积法生长条件和退火工艺对金刚石薄膜的消光系数和折射率的影响。实验表明金刚石薄膜中存在C—H、C=C、O—H和C=O键，生长条件对薄膜中C—H和C=C键的含量及薄膜的折射率影响较大；薄膜经过退火后薄膜的光学性质得到明显改善。     

电子助进化学气相沉积金刚石中发射光谱的蒙特卡罗模拟

采用蒙特卡罗方法，对源料气体为CH4/H2混合气的电子助进化学气相沉积（EACVD）中 的氢原子(H)、碳原子(C)以及CH基团的发射过程进行了模拟.研究了CH4浓度、反应室气压 和衬底偏压等工艺参数对发射光谱及成膜的影响.研究发现，CH基团可能是有利于金刚石薄 膜生长的活性基团，而碳原子不是；偏压的升高可提高电子平均温度及衬底表面附近氢原子 的相对浓度；通过氢原子谱线可测定电子平均温度并找到最佳成膜实验条件.该结果对EACVD 生长金刚石薄膜过程中实时监测电子平均温度，有效控制工艺条件，生长出高质量的金刚石 薄膜具有重要的意义. 关键词： 蒙特卡罗模拟 金刚石薄膜 发射光谱     

微波ECR全方位离子注入制备类金刚石碳膜的结构及摩擦学性能研究

利用微波ECR全方位离子注入技术，在单晶硅（100）衬底上制备类金刚石薄膜.分析结果表明，所制备的类金刚石碳膜具有典型的类金刚石结构特征，薄膜均匀、致密，表面粗糙度小，摩擦系数小.其中，薄膜的结构和性能与氢流量比关系密切，随氢流量比的增加，薄膜的沉积速率减小，表面粗糙度降低，且生成sp³键更加趋向于金刚石结构，表面能 更低，从而使摩擦系数大幅降低. 关键词： 全方位离子注入 类金刚石碳膜 拉曼光谱 摩擦磨损     

氮化铝单晶薄膜的ECR PEMOCVD低温生长研究

采用电子回旋共振等离子体增强金属有机物化学气相沉积（ECR－PEMOCVD）技术，在c轴取向的蓝宝石即α Al2O3（0001）衬底上，以氮化镓（GaN）缓冲层和外延层作为初始层，分别以高纯氮气（N2）和三甲基铝(TMAl)为氮源和铝源低温生长氮化铝（AlN）薄膜.并利用反射高能电子衍射（RHEED）、原子力显微镜（AFM）和x射线衍射（XRD）等测量结果，研究了氢等离子体清洗、氮化和GaN初始层对六方AlN外延层质量的影响，从而获得解理性与α Al2O3衬底一致的六方相AlN单晶薄膜，其XRD半高宽为1 关键词： AlN 氢等离子体清洗 氮化 GaN     

Investigation of optical emission spectroscopy in diamond chemical vapor deposition by Monte Carlo simulation

The optical emission spectra(atomic hydrogen(Hα,Hβ,Hγ),atomic carbon C(2p3s→2p2:λ=165.7 nm) and radical CH(A2△→X2П:λ=420-440 nm))in the gas phase process of the diamond film growth from a gas mixture of CH4 and H2 by the technology of electron-assisted chemical vapor deposition (EACVD)have been investigated by using Monte Carlo simulation.The results show that the growth rate may be enhanced by the substrate bias due to the increase of atomic hydrogen concentration and the mean temperature of electrons.And a method of determining the mean temperature of electrons in the plasma in-situ iS given.The strong dependence on substrate temperature of the quality of diamond film mainly attributes to the change of gas phase process near the substrate surface.     

OES study of the gas phase during diamond films deposition in high power DC arc plasma jet CVD system

This paper used optical emission spectroscopy (OES) to study the gas phase in high power DC arc plasma jet chemical vapour deposition (CVD) during diamond films growth processes. The results show that all the deposition parameters (methane concentration, substrate temperature, gas flow rate and ratio of H₂/Ar) could strongly influence the gas phase. C₂ is found to be the most sensitive radical to deposition parameters among the radicals in gas phase. Spatially resolved OES implies that a relative high concentration of atomic H exists near the substrate surface, which is beneficial for diamond film growth. The relatively high concentrations of C₂ and CH are correlated with high deposition rate of diamond. In our high deposition rate system, C₂ is presumed to be the main growth radical, and CH is also believed to contribute the diamond deposition.     

一种新型硅基3C-SiC的生长方法及光谱学表征

采用LPCVD技术, 以CH4和H2混合气体为反应源气, 在n-Si（111）衬底上生长3C-SiC晶体薄膜。H2在反应过程中作为稀释气体和运输气体, CH4作为碳源, 硅源有衬底硅来提供。利用X射线衍射分析仪、场发射扫描电子显微镜、激光拉曼光谱和傅里叶变换红外光谱分别研究3C-SiC薄膜的晶相结构、表面形貌及其光谱性质。结果表明此生长方法可以成功的成长出3C-SiC薄膜。     

电子助进化学气相沉积金刚石中衬底温度对发射光谱的影响

采用蒙特卡罗方法,对以CH4/H2为源料气体的电子助进化学气相沉积(EACVD)金刚石中的氢原子(H_α,H_β和H_γ)、碳原子C(2p3s→2p2: λ=165.7 nm)以及CH(A2Δ→X2Π: λ=420～440 nm)的发射过程进行了模拟,研究了衬底温度对各发射谱线以及金刚石膜合成的影响。结果得知,各谱线强度随衬底温度的变化幅度很小,且在衬底表面附近的谱线强度随衬底温度的变化幅度相对于远离衬底的反应区域较大,这表明衬底温度的变化基本上不改变远离衬底的反应区域中反应基团成分,而只对衬底表面附近的反应过程有影响。由此得知,衬底温度对薄膜质量的决定性主要是由于衬底温度改变了衬底表面化学反应动力学过程和表面附近的反应基团的缘故,而不是衬底温度对反应空间中气相成分的影响。     

Spatial characterization of H 2 :CH 4 dissociation level in microwave ECR plasma source by fibre-optic OES

Spatially resolved optical emission spectroscopy (SR-OES) was used to investigate microwave activated H₂/Ar/CH₄ plasma under conditions of the electron cyclotron resonance (ECR). The chemistry and composition of the gas phase were studied using self-designed fibre-optic system with echelle type spectrometer during CVD deposition of polycrystalline diamond. One-dimensional intensity profiles of the main species were collected along the vertical axis of chamber. The dominant species in the flux, originating from excited hydrogen and hydrocarbons, were identified as H, H⁺, CH and CH⁺; they are crucial for the diamond deposition process. The effect of ECR on the spatial distribution of H₂ and CH₄ dissociation profiles was studied in depth. The influence of processing parameters (gas flow rates, input power, pressure and magnetic field level) on species excitation as a function of the distance above substrate was asessed. The obtained data can be used for the ECR system optimization.     

Deposition and characterization of diamond epitaxial thin films on silicon substrates

Heteroepitaxial diamond growth has been attempted on mirror-polished monocrystalline (001), (111), and (110) silicon substrates by microwave plasma CVD. The surface morphology and the crystallographic properties of the films were characterized by means of Scanning Electron Microscopy (SEM), Raman spectroscopy, X-ray diffraction, and X-ray and Raman pole-figure analysis. The results demonstrate epitaxial growth of diamond on both (001) and (111) oriented silicon substrates. Preliminary results give strong evidence for substrate-induced orientation of the diamond crystallites also on (110) oriented silicon substrate. The heteroepitaxy can be assigned to the oriented covalent bonding across the interface between diamond and silicon.     

Study of microwave plasma-assisted chemical vapor deposition of poly-and single-crystalline diamond films

We study conditions for microwave plasma-assisted chemical vapor deposition of high-quality single-crystal diamond films in a CVD reactor. These conditions are studied using the results of homoepitaxial growth of polycrystalline diamond films on diamond substrates and on the basis of numerical simulation of the microwave discharge in a CVD reactor. A high-quality single-crystal diamond layer is synthesized on a synthetic, type Ib diamond substrate. The properties of the obtained monolayer are studied by means of Raman and X-ray diffraction spectroscopy as well as optical and atomic-force microscopy.     

Research of microstructural characteristics on nanocrystalline diamond by microwave plasma CVD

In this study, the nanocrystalline diamond (NCD) films were carried out by microwave plasma chemical vapor deposition (CVD) with CH₄/Ar/H₂ gas concoction on Si substrate at moderate temperatures. The characteristics of NCD films were evaluated using scanning electron microscopy, Raman spectroscopy, transmission electron microscopy, optical emission spectroscopy and optical contact angle meter. The analytical results revealed that C₂ radial was the dominant species in the deposited process. From TEM observation, the NCD films were formed via the etching of hydrocarbons and a small amount of H₂ content additive into gas mixture has improved the aggregation of the nucleation film to form the NCD films. The more hydrophobic surfaces imply that NCD films are the potential biomaterial in the application of article heart valve or stent.     

Growth and Characteristics of Freestanding Hemispherical Diamond Films by Microwave Plasma Chemical Vapor Deposition

Freestanding hemispherical diamond films have been fabricated by microwave plasma chemical vapor deposition using graphite and molybdenum （Mo） as substrates. Characterized by Raman spectroscopy and scanning electron microscopy, the crystalline quality of the films deposited on Mo is higher than that on graphite, which is attributed to the difference in intrinsic properties of the two substrates. By decreasing the methane concentration, the diamond films grown on the Mo substrate vary from black to white, and the optical transparency is enhanced. After polishing the growth side, the diamond films show an infrared transmittance of 35-60% in the range 400-4000 cm^- 1.     

高气压MPCVD沉积金刚石的光谱研究

采用微波等离子体化学气相沉积方法(microwave plasma chemical vapor deposition, MPCVD)在高沉积气压(34.5 kPa)下制备多晶金刚石,利用发射光谱(optical emission spectroscopy, OES)在线诊断了CH₄/H₂/O₂等离子体内基团的谱线强度及其空间分布,并利用拉曼(Raman)光谱评价了不同O₂体积分数下沉积出的金刚石膜质量,研究了金刚石膜质量的均匀性分布问题。结果表明：随着O₂体积分数的增加,C₂, CH及H_α基团的谱线强度均呈下降的趋势,而C₂,CH与H_α谱线强度比值也随之下降,表明增加O₂体积分数不仅导致等离子体中碳源基团的绝对浓度下降,而且碳源基团相对于氢原子的相对浓度也降低,使得金刚石的沉积速率下降而沉积质量提高。此外,具有刻蚀作用的OH基团的谱线强度却随着O₂体积分数的增加而上升,这也有利于降低金刚石膜中非晶碳的含量。光谱空间诊断发现高沉积气压下等离子体内基团分布不均匀,特别是中心区域C₂基团聚集造成该区域内非晶碳含量增加,最终导致金刚石膜质量分布的不均匀。