室温直流磁控溅射制备ITO膜及光电性能研究

室温条件下,在玻璃衬底上,采用直流磁控溅射法制备了ITO膜.研究了溅射压强,氧流量和溅射功率等工艺参数对薄膜光电性能的影响.结果表明当Ar流量为44.2 sccm和溅射时间20 min等参数不变时,溅射气压0.7 Pa,氧流量0.62 sccm和溅射功率130 W为最佳工艺条件.并得到了电阻率5.02×10-4 Ω·cm,在可见光区平均透过率80%以上ITO薄膜.     

溅射功率和氧分压对ITO薄膜光电性能的影响研究

采用直流反应磁控溅射法制备了氧化铟锡(ITO)透明导电薄膜,通过四探针、紫外可见分光光度计、X射线衍射(XRD)、霍尔效应仪、扫描电镜(SEM)等对薄膜样品进行了表征,研究了溅射功率和氧分压对ITO薄膜微观结构和光电性能的影响,结果表明:溅射功率对ITO的光电性能影响较小,沉积速率随着溅射功率的增大而加快;随着氧分压的升高,载流子浓度降低,霍尔迁移率先增大后减小,电阻率逐渐增大。在优化的工艺条件下,制备了在可见光区平均透过率达85%、电阻率为1×10-4Ω.cm的光电性能优良的ITO薄膜。     

磁控溅射低温沉积ITO薄膜及其光电特性研究

采用直流反应磁控溅射法低温沉积ITO薄膜,用XRD、SEM和UV—Vis分别表征ITO薄膜的晶体结构、表面形貌及其紫外-可见光吸收谱,研究了氧分压、溅射功率及薄膜厚度等工艺参数对薄膜光电性能的影响,结果表明,氧分压过大时,ITO薄膜中有大量的位错和缺陷,使薄膜的电阻率变大,导电性变差;氧分压过小时,薄膜中将有大量氧空位产生,导致晶格变形,使电阻率增加。随着溅射功率增大,在相同时间内薄膜厚度增加,方块电阻减小,薄膜电阻率降低。随着薄膜厚度增加,制备的薄膜晶体结构相对完整,载流子浓度和迁移率逐渐增大,薄膜电阻率变小,进而对样品的光电性能产生明显影响。     

磁控溅射制备ITO薄膜光电性能的研究

采用直流磁控溅射方法在玻璃基底上制备了ITO薄膜.分别用分光光度计和四探针仪测试了所制备ITO薄膜在可见光区域内的透过率和电阻率,研究了溅射气压、氧氩流量比和溅射功率三个工艺参数对ITO薄膜光电性能的影响.研究结果表明,制备ITO薄膜的最佳工艺参数为:溅射气压0.6 Pa,氧氩流量比1:40,溅射功率108 W.采用此工艺参数制备的ITO薄膜在可见光区平均透过率为81.18％,薄膜电阻率为8.9197×10-3Ω·cm.     

Ar气氛下直流磁控溅射ITO薄膜的结构和性能

采用直流磁控溅射法在低温、100%Ar的无氧气氛中制备了光电性能优良的铟锡氧化物(ITO,In2O3:SnO2=90:10,质量百分比)薄膜,详细探讨了溅射时改变氩气压强对ITO薄膜结构以及光电性能的影响.结果表明:溅射时氩气压强越小,ITO薄膜的体心立方晶型越完整,导电性越好,但对可见光透过性的影响不大.当氩气压强为0.3Pa时,溅射薄膜性能最佳,其光透过率可达92.9%,电导率为8.9×10-4Ω·cm.     

基于神经网络的AZO薄膜制备工艺参数的正交优化设计

采用磁控溅射法制备AZO薄膜,研究和讨论了溅射功率、溅射时间和溅射气压3个工艺参数对AZO薄膜光学和电学性能的影响。采用正交优化设计,对3个工艺参数进行优化,测量了透射率和电阻率,以此作为薄膜光电性能的评价指标,通过极差值分析确定了制备薄膜的最佳工艺参数。影响薄膜透射率的最主要因素为溅射气压;影响电阻率的最主要因素为溅射时间。获得制备高透射率低电阻率的AZO薄膜的最佳工艺组合方案为溅射功率为400W、溅射时间为1000s、溅射气压为1.0Pa。将反馈型(BP)神经网络应用于磁控溅射AZO薄膜光学性能(可见光区的平均透射率)和电学性能(电阻率)的研究。输入样品数据对神经网络进行训练,建立AZO薄膜光电性能随溅射参数变化的预测模型。     

磁控溅射制备增透ITO薄膜及其性能研究

用射频磁控溅射法在低温下制备了光电性能优良的ITO(In2O3:SnO2=1:1)薄膜。质量流量计调节氩气压强PAr为0.2～3.0Pa,氧流量fO2为0～10sccm,并详细探讨了溅射时PAr和fO2变化对ITO薄膜光学性能的影响。结果表明:fO2的改变引起薄膜中氧空位浓度变化而影响ITO薄膜折射率n;fO2对ITO靶材表面的溅射阀值和对Ar 散射而改变溅射速率。衬底表面粗糙度对ITO薄膜的折射率测量准确性有较大影响。PAr为0.8Pa,fO2为2.4sccm,薄膜厚度为241.5nm时,nmin=1.97,最大透过率为89.4%(包括玻璃基体),方阻为75.9?/□,电阻率为8.8×10-4?·cm。AFM分析表明薄膜表面针刺很少,表面平整(RMS=3.04nm)。     

直流磁控溅射法低温制备GZO:Ti薄膜及其光电性能研究

用直流磁控溅射法在玻璃衬底上成功制备出了钛镓共掺杂氧化锌(GZO:Ti)透明导电薄膜,研究了溅射压强和功率对GZO:Ti薄膜的微观结构和光电性能的影响。研究结果表明,所制备的GZO:Ti薄膜为六角纤锌矿结构的多晶薄膜,且具有c轴择优取向。溅射压强和功率对薄膜的电阻率和微观结构均有显著影响。随功率增大,薄膜电阻率降低,生长率增大。所制备的薄膜的最小电阻率为1.81×10-4Ω·cm,可见光区平均透过率大于84%。     

氩气压强对直流磁控溅射法制备ZnO:Nb透明导电薄膜性质的影响

室温下,利用直流磁控溅射法在玻璃衬底上制备了铌掺杂氧化锌(NZO)薄膜,研究了溅射压强(2～12 Pa)对薄膜结构、残余应力、表面形貌及其光电性能的影响.X射线衍射测量结果表明,所有样品都具有c轴择优取向的六角纤锌矿多晶结构,薄膜应力随压强的增大而减小.扫描电镜表明,随着溅射压强的增大,薄膜表面逐步趋向平整光滑、均匀致密.当溅射压强为10 Pa时,制备的ZnO∶Nb薄膜的最低电阻率可达3.52× 10-4 Ω·cm,残余应力为-0.37 GPa.压强由2Pa增大到12 Pa时,光学带隙由3.29eV增大到3.43 eV.紫外-可见透射光谱表明,所有薄膜在可见光范围内平均透过率均超过87％.     

无反应直流溅射中功率对ZnO：Al薄膜光电性能与形貌的影响

采用氧化锌铝陶瓷靶材，在室温下使用无氧直流磁控溅射法于载玻片衬底上制备了ZnO：Al透明导电薄膜，研究了溅射功率对薄膜微观结构、电阻率和透光率的影响。结果表明：薄膜具有六方纤锌矿结构并沿C轴择优取向生长，沉积速率与溅射功率呈准线性关系。溅射功率对薄膜的电阻率和表面形貌有显著影响，当功率为80w和120w时，薄膜的电阻率值为7．2×10^-3Ω·cm和2．3×10^-3Ω·cm，表面形貌分别为光滑与织构化,但溅射功率对薄膜的透光率影响不大，薄膜在可见光区的平均透光率均在90％左右。     

直流磁控溅射功率对ITO薄膜光学性能的影响

本实验的ITO薄膜样品是利用直流磁控溅射技术在玻璃基片上沉积而成的。通过改变溅射功率,研究不同溅射功率对ITO薄膜光学性能的影响。经各实验测试后发现：在实验给定的功率区间内,ITO薄膜的厚度随着溅射功率的增加而增加,其可见光透过率则随之降低。     

直流反应溅射TiO2薄膜的制备及其性能研究

采用直流反应磁控溅射的方法,溅射高纯钛靶在ITO石英衬底上制备了TiO2薄膜.用XRD、Raman光谱、AFM和紫外-可见光分光光度计分别测试了TiO2薄膜的结构、表面形貌和紫外-可见光透射谱,研究了工艺因素中溅射气压、氧氩比和退火温度对薄膜结构的影响.采用C(胶)/TiO2/ITO三层结构研究了锐钛矿TiO2薄膜的紫外光响应.实验结果表明较低的溅射气压、合适的氧氩比和较高的退火温度有利于锐钛矿TiO2薄膜的结晶.在2 V的偏压下,锐钛矿TiO2薄膜的紫外光响应上升迟豫时间约为3 s,稳定光电流可达到2.1 mA,对紫外光的灵敏性和稳定的光响应表明TiO2薄膜有可能成为一种新的紫外光探测器材料.     

Growth of ITO thin films by magnetron sputtering: OES study,opticaland electrical properties

In this work tin doped indium oxide (ITO) thin films were deposited onto soda lime glass substrates by the direct current magnetron sputtering system analyzing process of deposition with optical emission spectroscopy (OES). The dependence of electro-optical characteristics of the deposited films on the sputtering pressure, O₂/Ar working gas flow ratio and the discharge power was investigated. Transparency of the ITO films was measured using the ultraviolet and visible light spectrometer (UV–vis). The X-Ray photoelectron spectroscopy (XPS) method was applied for analysis of thin films surface chemical composition. It was found that in-situ measurement of plasma emission spectra allowed prediction and control of parameters of ITO thin films, namely resistivity and transparency. The correlation between the thin films resistivity, optical transparency and kinetics of deposition was examined.     

Structural instability of Sn-doped In2O3 thin films during thermal annealing at low temperature

We report on observations of structural stability of Sn-doped In₂O₃ (ITO) thin films during thermal annealing at low temperature. The ITO thin films were deposited by radio-frequency magnetron sputtering at room temperature. Transmission electron microscopy analysis revealed that the as-deposited ITO thin films are nanocrystalline. After thermal annealing in a He atmosphere at 250 °C for 30 min, recrystallization, coalescence, and agglomeration of grains were observed. We further found that nanovoids formed in the annealed ITO thin films. The majority of the nanovoids are distributed along the locations of the original grain boundaries. These nanovoids divide the agglomerated larger grains into small coherent domains.     

偏压对ITO薄膜生长模式和光电性能的影响

为明确溅射偏压对ITO薄膜性质的影响,用射频磁控溅射法于室温在玻璃衬底制备出ITO透明导电薄膜,研究了不同偏压下ITO薄膜的生长模式、光学和电学性能.结果表明:随着偏压的增加,薄膜沉积模式经历了沉积、沉积和扩散、表面脱附3种方式;AFM和SEM显示,偏压为100 V时,膜层表面光洁、均匀,粗糙度最小,均方根粗糙度为1.61 nm;XRD分析表明偏压会影响与薄膜的择优取向,偏压为100 V时,薄膜晶粒取向为(222)面;薄膜偏压为120 V时,薄膜的光电性能最佳,电阻率最低为2.59×10-4Ω.cm,可见光区的平均透过率在85%以上;偏压的大小使薄膜的吸收边发生了"蓝移"或"红移".     

Preparation of ITO thin films applied in nanocrystalline silicon solar cells

ITO thin films were prepared by changing the experimental parameters including gas flow ratio, sputtering pressure and sputtering time in DC magnetron sputtering equipment. The stable experimental parameters of Ar flow at 70 sccm, O₂ flow at 2.5 sccm ∼ 3.0 sccm, sputtering pressure around 0.5 Pa, and sputtering time of 80 s were obtained. Under these parameters, we had achieved the ITO thin films with low resistivity (<4 × 10⁻⁴ Ω ∙ cm) and high average transmissivity (95.48%, 350 nm ∼ 1100 nm). These ITO thin films were applied in nanocrystalline silicon solar cells as top transparent conductive layer. The solar cell test result showed that the open circuit voltage (Voc) was up to 534.9 mV and the short circuit current density (Jsc) was 21.56 mA/cm².     

用于紫外光电导探测器的TiO2薄膜研究

采用直流反应磁控溅射的方法,制备了TiO2薄膜。用X射线衍射,原子力显微镜(AFM)和紫外-可见光分光光度计分别测试了TiO2薄膜的晶体结构、表面形貌及其紫外-可见光吸收谱,采用C／TiO2／ITO三层结构制备了TiO2光电导型紫外探测器,研究了它的光响应。初步实验结果表明：TiO2薄膜在4W的紫光灯辐射下,光电流可达2．1mA,10min的辐射时间内,光电流基本保持稳定,可见TiO2薄膜对紫外光有较高的灵敏度和稳定性,可作为一种良好的紫外光探测材料。     

Preparation of ITO thin films applied in nanocrystalline silicon solar cells

ITO thin films were prepared by changing the experimental parameters including gas flow ratio, sputtering pressure and sputtering time in DC magnetron sputtering equipment. The stable experimental parameters of Ar flow at 70 sccm, O₂ flow at 2.5 sccm ∼ 3.0 sccm, sputtering pressure around 0.5 Pa, and sputtering time of 80 s were obtained. Under these parameters, we had achieved the ITO thin films with low resistivity (<4 × 10⁻⁴ Ω ? cm) and high average transmissivity (95.48%, 350 nm ∼ 1100 nm). These ITO thin films were applied in nanocrystalline silicon solar cells as top transparent conductive layer. The solar cell test result showed that the open circuit voltage (Voc) was up to 534.9 mV and the short circuit current density (Jsc) was 21.56 mA/cm².