GaSb薄膜生长的RHEED研究

采用分子束外延技术,在GaAs衬底上生长GaSb薄膜时,利用反射式高能电子衍射仪(RHEED)对衬底表面清洁状况、外延层厚度等进行在线监控.通过RHEED讨论低温缓冲层对GaSb薄膜表面结构和生长机制的作用,可以估算衬底温度,并能计算出薄膜的生长速率.实验测量GaSb的生长周期为1.96s,每秒沉积0.51单分子层.低温缓冲层提高了在GaAs衬底上外延GaSb薄膜的生长质量.     

碳化温度对异质外延3C-SiC薄膜结晶质量及表面形貌的影响

本文以Si(100)为衬底,利用水平式常压冷壁化学气相沉积(APCVD)系统在不同温度(1100～1250℃)下制备的“缓冲层”上生长了3C-SiC薄膜.结果表明,薄膜为外延生长的单一3C-SiC多型,薄膜表面呈现“镶嵌”结构特征,Si/3C-SiC界面平整无孔洞.碳化温度对薄膜的结晶质量和表面粗糙度有显著的影响,当碳化温度低于或高于1200℃时,薄膜的结晶质量有所降低,且随着碳化温度的升高,薄膜表面粗糙度呈现增大的趋势.当在1200℃下制备的“缓冲层”上生长薄膜时,可以获得最优质量的3C-SiC外延膜,其(200)晶面摇摆曲线半峰宽约为0.34°,表面粗糙度约为5.2nm.     

缓冲层厚度对MOCVD法生长GaN外延薄膜性能的影响

本文研究了低温GaN(LT-GaN)缓冲层表面形貌,其随厚度的变化规律及对随后生长GaN外延膜各项性能的影响.用场发射扫描电镜(SEM)和原子力显微镜(AFM)研究LT-GaN缓冲层表面形貌,发现随着厚度的增加,其表面由疏松、粗糙变得致密、平整,六角GaN小晶粒的数量减少,且取向较为一致.用X光双晶衍射(XRD)、AFM和Hall测量研究1μm厚本征GaN外延薄膜的结晶质量、表面粗糙度、背底载流子浓度和迁移率等性能,发现随着LT-GaN缓冲层厚度的增加:XRD的半高宽FWHMs增大,表面粗糙度先减小后又略有增大,背底载流子浓度则随之减少,而迁移率的变化则不明显.通过分析进一步确认LT-GaN缓冲层的最优生长时间.     

成核层温度对非掺杂GaN外延薄膜结晶质量的影响

利用金属有机化学气相沉积系统(MOCVD),在蓝宝石的(0001)面采用不同的成核层生长温度,通过两步法获得不同质量的GaN外延薄膜.利用HALL测试仪,高分辨X射线衍射仪(HRXRD),原子力显微镜(AFM)和光致发光光谱仪(PL)对GaN薄膜的表面形貌,位错密度,光学性能等进行表征,研究不同的成核温度对GaN外延薄膜晶体质量的影响.结果表明,在成核层生长温度为650℃时,所得到的GaN外延薄膜表面粗糙度和位错密度均达到最低,并且同时具有最高的带边发光峰强度,最高的载流子迁移率以及最低的载流子浓度.过低或过高的成核温度都会导致GaN外延层的晶体质量和光电性能变差.     

CeO_2缓冲层热处理对Tl-2212薄膜超导特性的影响

本文采用原子力显微镜(AFM)和XRD研究了生长在蓝宝石(11-02)基片上的CeO_2缓冲层在不同的退火温度和退火时间下表面形貌和相结构的变化,以及对Tl-2212薄膜超导特性的影响.AFM和XRD研究表明,CeO_2薄膜在流动氧环境中退火,表面形貌发生显著的变化;CeO_2薄膜在最佳条件下退火后,可获得原子级光滑表面,结晶质量明显提高.实验结果表明,缓冲层的结晶质量和表面粗糙度与Tl-2212薄膜的超导特性密切相关.在经过最佳条件退火后的CeO_2缓冲层上制备了厚度为500 nm无裂纹的Tl-2212超导薄膜,其临界转变温度(T_c)达到107 K,液氮温度下临界电流密度(J_c)为3.9 MA/cm~2(77 K,0 T),微波表面电阻(R_s)约为281 μΩ(77 K,10 GHz).     

MOCVD生长InxGa1-Xn薄膜的表征

本文利用MOCVD方法在(0001)取向的蓝宝石衬底上实现了不同生工艺条件下的InxGa-xN薄膜的制备,并通过XRD、SEM、AFM等测量分析方法系统研究了生长工艺参数对InxGa1-xN薄膜的组分和性质的影响.InxGa1-xN薄膜的制备包括蓝宝石衬底表面上GaN缓冲层的生长以及缓冲层上InxGa1-xN薄膜的沉积两个过程.通过对所制备InxGa1-xN薄膜的XRD、SEM、AFM分析发现,调节生长温度和TMGa的流量可以有效控制InxGa1-xN薄膜中In的组分,并且随着生长温度的升高,InxGa1-xN薄膜的表面缺陷减少.     

两步法溅射中缓冲层厚度对Ge薄膜质量的影响

采用低温缓冲层技术制备Ge薄膜,利用AFM和Raman光谱研究缓冲层厚度对低温Ge缓冲层残余应变弛豫的影响.实验结果显示:随着缓冲层厚度的增加,残余应变弛豫度增大.在30 nm厚的低温Ge缓冲层上生长800nm厚的Ge外延层.Ge薄膜具有良好的结晶性,表面粗糙度RMS为2.06 nm.     

在Si(100)上以AlN作过渡层低温外延生长ZnO薄膜

采用脉冲激光沉积(PLD)方法在Si(100)上成功生长了高度c轴取向的AlN薄膜,并以此为衬底,实现了ZnO薄膜的低温准外延生长.通过X射线衍射(XRD)、原子力显微镜(AFM)以及荧光分光光度计表征ZnO薄膜的结构、表面形貌和发光性能.结果表明,ZnO薄膜能在AlN过渡层上沿c轴准外延生长,采用AlN过渡层后,其荧光强度也有大幅提高.     

热壁外延制备InAs/Si(211)薄膜及其电学性能研究

采用热壁外延(Hot Wall Epitaxy,HWE)沉积系统在单晶Si(211)衬底表面制备了InAs薄膜,研究了不同生长温度(300℃、350℃、400℃、450℃和500℃)对薄膜材料结构及其电学性能的影响.通过X射线衍射(XRD)、扫描电子显微镜(SEM)、原子力显微镜(AFM)、霍尔(Hall)测试等,对InAs/Si(211)薄膜的晶体结构、表面形貌及电学参数进行了测试分析.结果表明:采用HWE技术在Si(211)衬底表面成功制备了InAs薄膜,薄膜具有闪锌矿结构并沿(111)方向择优生长.随着生长温度从300℃升高到500℃,全峰半高宽(FWHM)先减小后增大,生长温度为400℃时薄膜的晶粒尺寸最大为73.4 nm,载流子浓度达到1022 cm-3,霍尔迁移率数值约为102 cm2/(V·s),说明优化生长温度能够降低InAs薄膜的缺陷复合,使薄膜结晶质量和电学性能得到提高.SEM及AFM的测试结果显示由于较高的晶格失配及Si衬底斜切面(211)的特殊取向,在Si(211)衬底上生长的InAs薄膜主要为三维层加岛状(S-K)生长模式,表面粗糙度(Ra)随温度的升高先减小后增大,400℃时薄膜的平均表面粗糙度Ra为48.37 nm.     

AIC多晶硅薄膜的制备与其上HWCVD低温外延生长多晶硅薄膜的研究

铝诱导晶化法(AIC)是一种低温制备大晶粒多晶硅薄膜的重要方法.本文分别基于Al/Al2O3/a-Si叠层和a-Si/SiOx/Al叠层制备了AIC多晶硅薄膜,前者表面粗糙,后者表面光滑.以后者为籽晶层,在其上用HWCVD法300℃低温下外延生长了表面形貌与籽晶层相似的多晶硅薄膜.铝诱导晶化过程中,在原始非晶硅层中会形成多晶硅、非晶硅和铝的混合层,去除铝后残留的硅将使表面粗糙,而在原始铝层中则形成连续的多晶硅薄膜.Al/Al2O3/a-Si 叠层和a-Si/SiOx/Al叠层的上层分别是非晶硅层和铝层,发生层交换后,前者上层是硅铝混合层,因此表面粗糙,后者上层是连续的多晶硅薄膜,因此表面光滑.在AIC多晶硅薄膜表面外延生长多晶硅薄膜等效于铝诱导多晶硅的晶核在垂直于薄膜方向上的继续生长,因此外延生长的薄膜与AIC多晶硅薄膜呈现相似的枝晶状形貌.     

Effects of SiO2 overlayer at initial growth stage of epitaxial Y2O3 film growth

We investigated the dependence of the Y₂O₃ film growth on Si surface at initial growth stage. The reflection high-energy electron diffraction, X-ray scattering, and atomic force microscopy showed that the film crystallinity and morphology strongly depended on whether Si surface contained O or not. In particular, the films grown on oxidized surfaces revealed significant improvement in crystallinity and surface smoothness. A well-ordered atomic structure of Y₂O₃ film was formed on 1.5 nm thick SiO₂ layer with the surface and interfacial roughness markedly enhanced, compared with the film grown on the clean Si surfaces. The epitaxial film on the oxidized Si surface exhibited extremely small mosaic structures at interface, while the film on the clean Si surface displayed an island-like growth with large mosaic structures. The nucleation sites for Y₂O₃ were provided by the reaction between SiO₂ and Y at the initial growth stage. The SiO₂ layer known to hinder crystal growth is found to enhance the nucleation of Y₂O₃, and provides a stable buffer layer against the silicide formation. Thus, the formation of the initial SiO₂ layer is the key to the high-quality epitaxial growth of Y₂O₃ on Si.     

Vapour-phase epitaxial growth of ZnS on GaP

Single crystal layers of ZnS about 100 μm thick were grown epitaxially on GaP substrates in an open tube system using source ZnS powder and a flowing hydrogen atmosphere. The growth rate for different substrate temperatures increases with increasing hydrogen flow rate, but the growth rate profiles resemble each other in shape. The profile shifts towards the low temperature side as the source temperature is decreased. The (111)B substrate orientation is found to be preferable to the (111)A or the (100) with respect to surface morphology and crystal quality. X-ray diffraction investigations and luminescent properties show that the (111)B grown layers are of high quality. All ZnS layers grown on GaP substrates are craked on cooling, which may be due to the thermal expansion mismatch between the layer and the substrate. Heat-treatment of the grown layer does not reduce the resistivity, but increases the photoluminescence intensity markedly. Selective vapour-phase epitaxial growth has been successfully applied resulting in crack-free ZnS layers on GaP substrates.     

Analysis of ambient gas influence on silicon layers crystallized by means of LPE

Epitaxial growth of thin layers from the liquid phase can occur with the use of solutions saturated under different ambient gases. Most often this process takes place in a vacuum or gaseous atmosphere of hydrogen or argon. As the experimental data show, the morphology of crystallized layers is determined by the ambient type in which the process occurs.The cohesion energy responsible for epitaxial lateral deposition processes on the substrate surface depends on the surface free energy which is a measure of attraction of the solution atoms by substrate atoms. In the case of crystallization of an epitaxial lateral layer of Si on a substrate partially masked with dielectric, the chemical potentials of atoms in the neighboring phases (determining the interface evolution) are not without influence on the relaxation velocity of the saturated liquid phase, and on the horizontal and vertical growth rate.The aim of the investigation was to analyze experimentally the influence of the ambient gases used during the LPE growth on the cohesion of the Sn–Si solution with substrates applied for the lateral epitaxial growth of Si layers. This work presents comparative temperature analysis of the wetting angle of such surfaces as Si, SiO₂ and SiN_x by the Sn–Si solution.     

Stress control by micropits density variation in strained AlGaN/GaN/SiN/AlN/Si(111) heterostructures

AlGaN/GaN heterostructures were deposited on Si utilizing in‐situ SiN masking layer as a mean to decrease stress present in the final heterostructures. Structures were grown under different V/III ratio using metalorganic vapour phase epitaxy (MOVPE). Additional approach was applied to obtain crack‐free heterostructures which was deposition of 15 nm low temperature AlN interlayer. Each of the heterostructure contained GaN layer of 2.4 μm total thickness. In‐situ SiN masking layer were obtained via introduction of SiH4 precursor into reactor under high temperature growth conditions for 100 s. In that manner, few monolayers of SixNx masking layer were deposited, which due to the partial coverage of AlN, played role of a mask leading to initial 3D growth mode enhancing longer coalescence of GaN buffer layer. To study surface morphology AFM images were observed. Three methods were used in order to obtain basal plane stress present in multilayer structures ‐ MicroRaman spectroscopy, XRD studies and optical profilometry. It was found that varying V/III precursors ratio during GaN layer growth characteristic for structures with the SiN mask approach formation of triangular micropits can be minimized. Outcomes for three different methods turned out to be coherent. It was found that certain amount of micropits on the surface can be advantageous lowering stress introduced during cooling after process to the AlGaN/GaN/SiN/AlN/Si(111) structure.     

Solid phase epitaxial growth of Si through Al film

Uniform epitaxial growth has been obtained by dissolution and transport of an evaporated Si film through an evaporated Al film at temperatures below 500°C. By analyzing the samples made in different ways we show that the presence of a cap on the metal layer, which inhibits the diffusion of the metal through the evaporated Si, plays a fundamental role. The cap consists of a thin oxide layer grown on top of the metal. The cap is made by leaving the sample in vacuum for two days or by heating the sample in vacuum before the Si deposition. The study of the initial growth rate on 〈100〉 and 〈111〉Si substrates reveals that the growth starts as islands which grow until they coalesce to form a continuous layer. Different growth rates have been obtained by using 〈100〉 and 〈111〉Si substrates. Typical growth rates are 50 Å/min at 330°C on 〈100〉 and 100 Å/min at 392°C on 〈111〉. The activation energy of the process is 1.2 eV.     

AlN buffer layer growth for GaN epitaxy on (1 1 1) Si: Al or N first?

AlN is generally used as buffer layer for the epitaxial growth of GaN on Si(1 1 1) substrate. In this work, we specifically address the relationship between the way the AlN growth is initiated on the Si(1 1 1) surface and the overall properties of the final GaN epitaxial layer. The growth is performed by molecular beam epitaxy with ammonia (NH₃) as nitrogen source. Two procedures have been compared: exposing the Si surface first to NH₃ or Al. The AlN nucleation is followed in real-time by reflection high-energy electron diffraction and critical stages are also investigated in real space using scanning tunnelling microscopy and transmission electron microscopy. Atomic force microscopy, X-ray diffraction and photoluminescence are also used to assess the properties of the final GaN epitaxial layer. It is shown that best results in terms of GaN overall properties are obtained when the growth is initiated by exposing the Si(1 1 1) surface to NH₃ first. This is mainly due to the fact that almost an order of magnitude decrease of the dislocation density is obtained.     

AlN/Si(100)上CVD SiC薄膜的光致发光谱

本工作用化学气相淀积方法在AlN/Si(100)复合衬底上生长SiC薄膜.外延生长过程中,采用C4H4和SiH4作为反应气源,H2作为载气.样品的X-射线衍射谱和拉曼散射谱显示,所得到的外延层为六角对称的SiC薄膜.俄歇电子能谱及X-射线光电子能谱的测量结果表明,在外延膜中存在来自衬底的Al和N元素.样品的光致发光测量显示,所有的样品均可在室温下观察到位于3.03eV和3.17eV处的发光峰,这分别相应于4H-SiC能带中电子从导带到Al受主能级之间的辐射跃迁和电子从N施主能级到价带之间的辐射跃迁,从而表明所得的外延薄膜的多形体为4H-SiC.     

Electron Microscopy Study of Surface Islands in Epitaxial Ge3Sb2Te6 Layer Grown on a Silicon Substrate

Crystallography Reports - Islands in the form of truncated triangular pyramids on the surface of an epitaxial Ge3Sb2Te6 layer grown on a Si(111) substrate are identified by scanning electron...