镶嵌有纳米硅的氮化硅薄膜键合特性分析

采用螺旋波等离子体化学气相沉积(HWPCVD)技术制备了非化学计量比的氢化氮化硅薄膜,对所沉积样品及氮气环境中920℃退火样品的微观结构及键合特性进行了分析.Raman散射结果表明,薄膜中过量硅以非晶纳米粒子形式存在,退火样品呈现纳米晶硅和氮化硅的镶嵌结构.红外吸收和可见光吸收特性比较结果显示,薄膜样品的微观结构依赖于化学计量比以及退火过程,硅含量较低样品因高的键合氢含量而表现出低的纳米硅表面缺陷态密度;退火过程将引起Si-H和N-H键合密度的减少,因晶态纳米颗粒的形成,退火样品表现出更高的结构无序度.     

纳米晶硅薄膜中氢含量及键合模式的红外分析

采用传统射频等离子体化学气相沉积技术在100—350℃的衬底温度下高速沉积氢化硅薄膜. 傅里叶变换红外光谱和Raman谱的研究表明，纳米晶硅薄膜中的氢含量和硅氢键合模式与薄膜的晶化特性有密切关系，当薄膜从非晶相向晶相转变时，氢的含量减少了一半以上，硅氢键合模式以SiH₂为主. 随着衬底温度的升高和晶化率的增加，纳米晶硅薄膜中氢的含量以及其结构因子逐渐减少. 关键词： 氢化纳米晶硅薄膜 红外透射谱 氢含量 硅氢键合模式     

氮化硅薄膜中纳米非晶硅颗粒的键合结构及光致发光

采用螺旋波等离子体化学气相沉积技术以N₂/SiH₄/H₂为反应气体制备了镶嵌有纳米非晶硅颗粒的氢化氮化硅薄膜，通过改变N₂流量实现了薄膜从红到蓝绿的可调谐光致发光.傅里叶红外透射和紫外-可见光吸收特性分析表明，所生长薄膜具有较高的氢含量，N₂流量增加使氢的键合结构发生变化，非晶硅颗粒尺寸减小，所对应的薄膜的光学带隙逐渐增加和微观结构有序度减小.可调光致发光(PL)主要来源于纳米硅颗粒的量子限制效应发光，随N₂流量增加，PL的谱线展宽并逐渐增强. 关键词： 傅里叶红外透射谱 光吸收谱 纳米硅粒子镶嵌薄膜 光致发光     

氢化非晶硅薄膜中氢含量及键合模式的红外分析

Fourier红外透射(FTIR)谱技术是研究氢化非晶硅（a-Si∶H）薄膜中氢的含量（CH）及硅—氢键合模式（Si-Hn）最有效的手段.对用等离子体化学气相沉积（PCVD）方法在不同的衬底温度（Ts）下制备出的氢化非晶硅薄膜，通过红外透射光谱的基线拟合、高斯拟合分析，得到了薄膜中的氢含量，硅氢键合模式及其组分，并分析了这些参量随衬底温度变化的规律.     

不同退火温度下晶化硅薄膜的电学输运性质

采用等离子体化学气相沉积技术制备氢化非晶硅薄膜，经过不同温度下的热退火处理，使薄膜由非晶结构向晶化结构转变，得到含有纳米晶粒的晶化硅薄膜.在晶化过程中，采用Raman技术对样品的结构进行表征.通过变温电导率的测试，对薄膜的电学输运性质进行了分析.研究结果表明：退火温度为700 ℃时,样品中开始有纳米晶形成，随着退火温度的增加，样品的晶化比增大，在1000 ℃时，薄膜的晶化比达到90%以上.在700 ℃退火时，薄膜中晶化成分较低，载流子的传输特性主要受到与硅悬挂键有关的缺陷态影响，表现为带尾定域态的跳跃电导 关键词： 氢化非晶硅 退火 纳米硅 电输运     

氢稀释对FTS沉积a-Si:H薄膜结构特性的影响

采用对靶磁控反应溅射技术,以氢气作为反应气体在不同的氢稀释比条件下制备了氢化非晶硅薄膜.利用台阶仪、傅里叶红外透射光谱、Raman谱和紫外-可见光透射谱测量研究了不同氢稀释比对氢化非晶硅薄膜生长速率和结构特性的影响.分析结果发现,利用对靶磁控溅射技术能够实现低温快速沉积高质量氢化非晶硅薄膜的制备.随着氢稀释比不断增加,薄膜沉积速率呈现先减小后增大的趋势.傅里叶红外透射光谱表明,氢化非晶硅薄膜中氢含量先增大后变小.而Raman谱和紫外-可见光透射谱分析发现,氢稀释比的增加使氢化非晶硅薄膜有序度和光学带隙均先增大后减小.可见,此技术通过改变氢稀释比R能够实现氢化非晶硅薄膜结构的有效控制.     

氢稀释对FTS沉积a-Si∶H薄膜结构特性的影响

采用对靶磁控反应溅射技术,以氢气作为反应气体在不同的氢稀释比条件下制备了氢化非晶硅薄膜.利用台阶仪、傅里叶红外透射光谱、Raman谱和紫外-可见光透射谱测量研究了不同氢稀释比对氢化非晶硅薄膜生长速率和结构特性的影响.分析结果发现,利用对靶磁控溅射技术能够实现低温快速沉积高质量氢化非晶硅薄膜的制备.随着氢稀释比不断增加,薄膜沉积速率呈现先减小后增大的趋势.傅里叶红外透射光谱表明,氢化非晶硅薄膜中氢含量先增大后变小.而Raman谱和紫外-可见光透射谱分析发现,氢稀释比的增加使氢化非晶硅薄膜有序度和光学带隙均先增大后减小.可见,此技术通过改变氢稀释比R能够实现氢化非晶硅薄膜结构的有效控制.     

氧掺入对纳米硅薄膜微结构及能带特性的影响

采用等离子体增强化学气相沉积法(PECVD)制备了富硅氧化硅薄膜,利用XRD衍射仪,傅里叶变换红外透射光谱仪以及紫外-可见光分光光度计分析了氧掺入对薄膜微观结构以及能带特性的影响。结果表明,随着氧掺入比(CO2/SiH4)的增加,薄膜晶粒尺寸减小,晶化度降低,纳米硅(nc-Si)表面的张应力先增加后减小。红外吸收谱分析表明,氧掺入比增加导致薄膜内氧含量增高,富氧Si—O键合密度增加,富硅Si—O键合密度降低。同时,薄膜结构因子减小,有序度增大,薄膜微观结构得到改善。当氧掺入比大于0.08时,薄膜结构因子增大,有序度降低。此外,氧掺入增加导致薄膜带隙不断增加,带尾宽度呈现先减小后增大的趋势。因此,通过氧掺入可以调节纳米硅薄膜微观结构及能带特性,氧掺入比为0.08时,薄膜具有高晶化度和较宽的带隙,微观结构得到有效改善,可用作薄膜太阳能电池的本征层。     

微量掺碳nc-SiC:H薄膜用于p-i-n太阳电池的窗口层

采用等离子增强化学气相沉积方法(PECVD)制备了微量掺碳的p型纳米非晶硅碳薄膜(p-nc-SiC：H)，反应气体为硅烷和甲烷，掺杂气体采用硼烷，沉积温度分别采用333K，353K和373K.测量结果表明随着沉积温度增加和碳含量的增加，薄膜的光学带隙增加；薄膜具有较宽的带隙和较高的电导率，同时有较低的激活能(0.06eV).Raman和XRD测量结果表明薄膜存在纳米晶.优化的p型纳米非晶硅碳薄膜作为非晶硅p-i-n太阳电池的窗口层，使得太阳电池的开路电压达到0.94V. 关键词： 光学带隙 纳米硅 薄膜 太阳能电池     

氮掺入对N型纳米硅薄膜微观结构及光电特性影响

采用等离子体增强化学气相沉积技术(PECVD)通过改变NH3流量制备出不同含氮量N型富硅氮化硅硅薄膜.利用Raman散射、红外吸收、紫外-可见光分光光度计及暗态I-V测量等技术分析了氮掺入对薄膜微观结构以及光电特性的影响.结果显示,随着NH3的增加,薄膜由微晶硅向纳米硅结构转变,薄膜中晶粒尺寸减少,晶化度降低,微观结构有序性降低,所对应薄膜光学带隙增大,而带尾分布变窄.同时,红外吸收谱分析表明,S i-N键合密度增加,P掺杂受阻.暗态I-V测量显示,薄膜电导率随着NH3掺入整体较微晶硅降低,但随NH3增加,电导率受到迁移率和载流子浓度等特征共同作用先降低后变大,揭示了影响薄膜电导率的机制存在一定的竞争,然而过高的非晶网络结构将增大载流子的复合导致薄膜电导率显著降低.     

Influences of hydrogen dilution on microstructure and optical absorption characteristics of nc-SiO_x:H film

By using the plasma enhanced chemical vapor deposition(PECVD) technique, amorphous silicon oxide films containing nanocrystalline silicon grain(nc-Si O x:H) are deposited, and the bonding configurations and optical absorption properties of the films are investigated. The grain size can be well controlled by varying the hydrogen and oxygen content,and the largest size is obtained when the hydrogen dilution ratio R is 33. The results show that the crystallinity and the grain size of the film first increased and then decreased as R increased. The highest degree of crystallinity is obtained at R = 30.The analyses of bonding characteristics and light absorption characteristics show that the incorporation of hydrogen leads to an increase of overall bonding oxygen content in the film, and the film porosity first increases and then decreases. When R = 30, the film can be more compact, the optical absorption edge of the film is blue shifted, and the film has a lower activation energy.     

生长温度对ZnO薄膜晶体质量和发光特性的影响

采用激光脉冲沉积法在Si(100)衬底上生长ZnO薄膜,衬底温度分别为室温,200℃,300℃,400℃和500℃.用X射线衍射仪、拉曼光谱、扫描电子显微镜对薄膜的微结构进行了测量,并测量了室温下薄膜的光致发光特性.结果表明,300℃时.ZnO具有最佳择优取向,随着衬底温度升高.衍射峰半峰全宽减小,薄膜晶粒尺寸增大,400℃时,薄膜具有各向等大的品粒尺寸.同时拉曼谱结果显示,薄膜内部的缺陷随衬底温度变化无明显差别,应力表现为张应力,400℃时应力最小,紫外发光峰在衬底温度为400℃时最强,而黄绿光带最弱.在减少薄膜缺陷,提高择优长向和晶粒尺寸的同时.使晶粒横向尺寸和纵向尺寸尽可能相同,可极大提高薄膜的发光特性.     

Influence of substrate temperature on growth of a-Si:H films by reactive facing target sputtering deposition

Hydrogenated amorphous silicon(a-Si:H) films were deposited by reactive facing target sputtering(FTS) technique with a mixture of Ar and H2 reaction gas.Fourier transform infrared(FTIR) absorption,Raman scattering and ultraviolet-visible optical absorption are used to investigate the microstructure and optical properties of the deposited films.The decrease of the concentration of bonded hydrogen,especially that of(Si-H2)n with increasing substrate temperature(Ts),was observed in FTIR spectra,suggesting the ...     

氢稀释制备的非晶碳膜的绿光和蓝光发射

在电容耦合式PECVD系统中,以CH4和H2为气源,通过控制H2的流量制备了一系列氢化非晶碳膜（a-C:H)样品。利用傅里叶变换红外光谱（FTIR）、光致发光谱（PL）和吸收谱对a-C:H膜的结构及光学性质进行了研究。结果表明：氢稀释可以在一定程度上减少碳的sp^2团簇的形成,增大它的光学带隙,并改变薄的微结构。与此同时,光致发光峰随郑 光学带隙的增大而蓝移;当光学带隙增大2．72eV时,出现了2．4eV（绿光）和2．97eV(蓝光）组成的发光峰。     

Silicon rich silicon oxide films deposited by radio frequency plasma enhanced chemical vapor deposition method: Optical and structural properties

Silicon rich silicon oxide films have been deposited by plasma enhanced chemical vapour deposition using a gas mixture of silane, carbon-di-oxide and hydrogen. Silicon nanocrystals formations in the as deposited silicon rich silicon oxide films have been detected by high resolution transmission electron microscopy, scanning electron microscopy, Raman scattering and X-ray diffraction studies. Structural changes under different deposition condition have been studied by Fourier transform infrared spectroscopy. The oxygen and hydrogen bonding configurations have been obtained from Fourier transform infrared spectroscopy. Room temperature photoluminescence spectra have been observed for the as deposited films. The structural properties together with photoluminescence spectra allowed us to gain insight about the Si nanocrystal formation.     

溅射制备非晶氮化镓薄膜的光学性能

采用直流磁控溅射方法在不同的氩气-氮气（Ar-N₂）气氛中制备了非晶氮化镓（a-GaN）薄膜. X射线衍射分析（XRD）和拉曼光谱（Raman）表明薄膜具有非晶结构. 通过椭偏光谱（SE）得到薄膜的折射率和厚度都随着氩气分量的增多而增大. 紫外—可见光谱（UV-Vis）的测量得到，当氩气分量R，即Ar/（Ar+N₂），为0%时，薄膜的光学带隙为3.90eV，比晶体GaN （c-GaN） 的较大，这主要是由非晶结构中原子无序性造成的；而当R关键词： 非晶氮化镓 溅射 光学带隙 带尾态     

The optoelectronic properties of silicon films deposited by inductively coupled plasma CVD

Hydrogenated amorphous and microcrystalline silicon films were deposited by inductively coupled plasma chemical vapor deposition (ICP-CVD) at low substrate temperatures using H₂-diluted SiH₄ as a source gas. High-density plasma generated by inductively coupled excitation facilitates the crystallization of silicon films at low temperatures, and microcrystalline silicon films were obtained at the substrate temperature as low as 180 °C. The columnar structure of the films becomes more and more compact with an increase of their crystallinity. The reduction of hydrogen content in the films causes a narrowing of the optical bandgap and an enhancement of the absorption with increasing the substrate temperature. The microcrystalline silicon films show two electronic transport mechanisms: one is related to the density of state distribution in the temperature region near room temperature and the other is the variable range hopping between localized electronic states close to the Fermi level below 170 K. A reasonable explanation is presented for the dependence of the optoelectronic properties on the microstructure of the silicon films. The films prepared at a substrate temperature of 300 °C have highly crystalline and compact columnar structure, high optical absorption coefficient and electrical conductivity, and a low hydrogen content of 3.8%.     

非晶碳化硅材料与光学微腔的制备与发光

利用等离子体化学气相沉积技术在100℃的衬底温度下,制备了具有不同组分比的系列非晶碳化硅薄膜。结合傅里叶变换红外光谱与喇曼光谱对所制备的薄膜微结构进行了表征与分析,同时,对具有不同组分比的非晶碳化硅薄膜室温光致发光性质进行了系统的研究。结果表明在Ar⁺离子激光和Xe灯紫外光的激发下,不同组分的样品显示出不同的光致发光特性,并对样品的发光特性与其微结构的联系进行了讨论。在此基础上,用碳化硅薄膜设计和制备了全固体光学微腔,研究了微腔对碳化硅发光行为的调制作用。     

Preparation of hydrogenated microcrystalline silicon films with hot-wire-assisted MWECR-CVD system

Intrinsic hydrogenated microcrystalline silicon （μc-Si：H） films have been prepared by hot-wire-assisted microwave electron-cyclotron-resonance chemical vapour deposition （HW-MWECR-CVD） under different deposition conditions, Fourier-transform infrared spectra and Raman spectra were measured. Optical band gap was determined by Tauc plots, and experiments of photo-induced degradation were performed. It was observed that hydrogen dilution plays a more essential role than substrate temperature in microcrystalline transformation at low temperatures. Crystalline volume fraction and mean grain size in the films increase with the dilution ratio （R=H2/（H2＋SiH4））. With the rise of crystallinity in the films, the optical band gap tends to become narrower while the hydrogen content and photo-induced degradation decrease dramatically. The samples, were identified as μc-Si：H films, by calculating the optical band gap. It is considered that hydrogen dilution has an effect on reducing the crystallization activation energy of the material, which promotes the heterogeneous solid-state phase transition characterized by the Johnson-Mehl-Avrami （JMA） equation. The films with the needed structure can be prepared by balancing deposition and crystallization through controlling process parameters.