高k HfLaO栅介质MoS2晶体管的性能研究

比较研究了HfO₂与HfLaO栅介质多层MoS₂场效应晶体管。实验结果表明,与HfO₂栅介质MoS₂晶体管相比,HfLaO栅介质MoS₂晶体管表现出更优的电性能。电流开关比高达1×10⁸,亚阈斜率低至76 mV/dec,界面态密度低至1.1×10¹² cm-2·eV-1,载流子场效应迁移率高达1×10⁹ cm²·V-1·s-1。性能改善的原因在于镧(La)对HfO₂的掺杂形成HfLaO化合物,减小栅介质薄膜的表面粗糙度,降低缺陷电荷密度,改善了栅介质/沟道界面特性,从而减小了界面态密度,抑制了库仑散射和界面粗糙散射。最终,提高了多层MoS₂晶体管的场效应迁移率,改善了晶体管的亚阈特性。     

In0.53Ga0.47As表面氮化和硫钝化对其Al/Al2O3/InGaAs MOS电容特性的影响

本文通过对比频散特性和滞回特性,计算界面态密度D_it和有效边界缺陷密度ΔN_bt,分析界面缺陷和漏电流等方法,系统的研究了In_0.53Ga_0.47As表面氮化和硫钝化对其Al/Al₂O₃/InGaAs结构MOS电容特性的影响。实验结果表明,这两种方法都能够在InGaAs表明形成一层界面钝化层。相比较于未处理的样品,经过氮气等离子体处理的样品表现出较好的界面特性,得到了最小的积累区频散、滞回电压,以及良好的I-V性能。经过(NH₄)₂S_x处理的样品则获得了最小的平带电压区频散以及最低的界面态密度Dit=2.6E11cm_-2eV_-1.     

ZrON/GeON 双钝化层改善Ge MOS器件的界面特性和电特性

本文研究了利用等离子体氮化形成ZrON/GeON双钝化层制备Ge MOS器件的界面特性和电特性。结果发现,相比于N2等离子处理,NH3等离子处理制备的双钝化层显著改善了器件的界面和电特性,获得了低的界面态密度 (Dit = 1.64×1011 cm-2 eV-1)和栅极漏电流(Jg = 9.32×10-5 A cm-2@Vfb +1 V),小的电容等效厚度 (CET = 1.11 nm)以及高的k值 (32). XPS分析表明,由NH3等离子体分解出的H原子和NH基团可以有效促进Ge表面不稳定低k GeOx的挥发,从而形成了高质量的GeON钝化层;且NH3等离子体氮化导致更多氮在ZrON/GeON中结合,能更有效阻止O、Ti、Ge等元素间的相互扩散,从而获得好的界面质量和电特性。     

SiNx/SiOxNy叠层结构防潮能力的研究

研究了等离子体增强化学气相沉积(PECVD)工艺参数对SiN_x及SiO_xN_y防潮能力的影响,并测试了SiN_x/SiO_xN_y叠层薄膜的水汽渗透速率(WVTR)。实验结果表明:单层SiN_x薄膜和SiO_xN_y薄膜都存在临界厚度,当膜厚大于临界值时,继续增大厚度不会明显改善薄膜的WVTR。当沉积温度从50℃提高到250℃,SiN_x薄膜的WVTR从0.031g/(m²·day)降至0.010g/(m²·day)。SiO_xN_y沉积时,增大N₂O通入量对薄膜的WVTR影响不明显,但可以有效改善薄膜的弯曲性能。最后,4个SiN_x/SiO_xN_y叠层膜的WVTR下降到了4.4×10-4g/(m²·day)。叠层膜防潮能力的显著提升归因于叠层结构可以有效解耦层与层之间的缺陷,延长水汽渗透路径。     

氧分压对射频溅射制备ZTO沟道层的薄膜晶体管器件性能的影响

以锌锡氧化物(ZTO)薄膜作为沟道层,聚甲基丙烯酸甲酯(PMMA)薄膜作为介质层低温(100℃)制备了顶栅共面结构的薄膜晶体管(TFT),并研究了ZTO沟道层成膜过程中氧分压对器件性能的影响。结果表明,ZTO沟道层具有稳定的非晶结构、较高的可见光透明性(在400~700nm范围内平均透过率大于等于89.61%),且增大氧分压有利于其可见光透明性的提升。霍尔测试结果表明,增大氧分压(由3.5×10-2Pa增大到7.5×10-2Pa)会降低ZTO电子载流子浓度(由4.73×10¹⁵cm-3降低到6.11×10¹²cm-3),致使基于ZTO沟道层TFT器件的能耗降低(表现为关态电流的降低和耗尽型器件阈值电压的正向移动)。此外,增大氧分压还有益于沟道层/介质层界面状态的优化,即亚阈值摆幅减小。     

沉积气压对脉冲激光沉积CNx薄膜结构和摩擦学特性的影响

以脉冲激光沉积(PLD)的CNx材料为靶源,以单晶Si片为衬底,在N₂气压为2～11Pa 下PLD制备了CNx薄膜。采用X射线光电子能谱(XPS)、拉曼 (Raman)光谱、扫描 电子显微镜(SEM)和球盘式摩擦磨损试验机分别对薄膜的化学成分、价键状态、表面形貌和 摩擦性能进行了表征。结果表明:低沉积气压导致薄膜N含量的退化及耐磨性能的下降;沉 积气压介于5～8Pa时最利于sp³杂化键的形成,且薄 膜的N含 量缓慢下降,膜中比值x_sp²/x_sp³和ID/IG均减 小,x_sp²C-N/x_sp³C-N增加并趋于恒定,薄膜的耐磨性较好(约2.7～4.3×10 －15 m³·N－1·m－1),但摩擦系数相对较高(约0.24～0.25);过高的气压导致膜层中 N含量的下降和石墨化程度的增加,薄膜摩擦系数较低(约0.19), 但耐磨性呈下降趋势。     

基于多次反射样品池的TDLAS逃逸NH3检测研究

时域激光吸收光谱(TDLAS)技术具有高选择性、 高准确性优点,为逃逸NH₃的在线检测提供了可靠的技术手段。本文利用TDLAS 系统分别在White和Herriott 两种样品池中对浓度为(10～100)×10－6的NH₃进行检测, 采集得到其二次谐波光谱,比较 了两种样品池测量结果,分析对比两种样品池的优缺点。实验显示,Herriott样品池的噪声 要大,根据光谱曲线的标准偏差得到White样品池最低检出限为1.21×10－6 ,Herriott样品池 的检测限为1.61×10－6。结果表明,Herriott样品池更适合 恶劣环境现场应用,能够满足逃逸NH₃的痕量检测要求,适合在线监测。     

Ni-Au/AlN/Si器件的深能级瞬态谱研究

对GaN器件制备过程中AlN缓冲层相关的电活性缺陷进行了C-V和深能级瞬态谱(DLTS)研究。C-V研究结果表明,制备态Ni-Au/AlN/Si MIS器件中,靠近AlN/Si界面处的掺杂浓度为4.4×10¹⁷cm-3,明显高于Si衬底的1.4×10¹⁶cm-3,意味着制备态样品中Al原子已经向衬底硅中扩散。采用退火工艺研究了GaN器件制备过程中的热影响以及热处理前后电活性缺陷在硅衬底中的演变情况,发现退火处理后,Al原子进一步向衬底硅中更深处扩散,扩散深度由制备态的500nm左右深入到1μm附近。DLTS研究结果发现,在Si衬底中与Al原子扩散相关的缺陷为Al-O配合物点缺陷。DLTS脉冲时间扫描表明,相比于制备态样品,退火态样品中出现了部分空穴俘获时间常数更大的缺陷,退火处理造成了点缺陷聚集,缺陷类型由点缺陷逐渐向扩展态缺陷发展。     

LiYF4:Tm3＋单晶的生长及其光学性能研究

采用坩埚下降法,制备了尺寸为Φ10mm×110mm的高质量Tm³⁺掺杂LiYF₄(YLF :Tm3＋)单晶体。测试了样品的电感耦合等离子(ICP)、X光衍射(XRD)吸收光谱 以及790nm LD激发 下的荧光光谱。应用Judd-Ofelt理论计算了Tm³⁺在YLF∶Tm3＋单晶 材料中的唯象强度参数Ω_t、能级跃迁振子强度Pexp、 自发辐射跃迁几率A、荧光分支比β和辐射寿命τrad 等光谱参数,同时计算了1800nm波段的吸收截 面和受激发射截面分别 为σabs=0.52×10－20 cm²和σem=0.67×10 －20 cm²。在荧光光谱中观察到1470nm与1 800nm的荧光发射,它们分别对应于Tm³⁺的³H₄→³F ₄与³F₄→³H₆的能级跃迁。测定了1800nm波段的荧光寿命 ,并计算得到³F₄→³H₆跃迁的量子效率为79.22%。     

具有低噪声及高线性度的高性能MOCVD-SiNx/AlN/GaN 毫米波MIS-HEMTs

文章在超薄势垒AlN/GaN异质结构上采用金属有机化学气相沉积（MOCVD）原位生长SiN_x栅介质,成功制备了高性能的SiN_x/AlN/GaN金属-绝缘体-半导体高电子迁移率晶体管（MIS-HEMTs）。深能级瞬态谱（DLTS）技术测试SiN_x/AlN的界面信息,显示其缺陷能级深度为0.236 eV,俘获截面为3.06×10^-19 cm^-2,提取的界面态密度为10¹⁰~10¹² cm^-2eV^-1,表明MOCVD原位生长的SiN_x可以有效降低界面态。同时器件表现出优越的直流、小信号和噪声性能。栅长为0.15 μm的器件在2 V的栅极电压（V_gs）下具有2.2 A/mm的最大饱和输出电流,峰值跨导为506 mS/mm,最大电流截止频率（f_T）和最大功率截止频率（f_MAX）分别达到了65 GHz和123 GHz,40 GHz下的最小噪声系数（NF_min）为1.07 dB,增益为 9.93 dB。V_ds = 6 V时对器件进行双音测试,器件的三阶交调输出功率（OIP3）为32.6 dBm,OIP3/P_dc达到11.2 dB。得益于高质量的SiN_x/AlN界面,SiN_x/AlN/GaN MIS-HEMT显示出了卓越的低噪声及高线性度,在毫米波领域具有一定的应用潜力。     

Resolution Enhancement Technology:Integrated Process Solutions using OPC

DUV lithography, using the 248 nm wavelength, is a viable manufacturing option for devices with features at 130 nm and less. Given the low kl value of the lithography, integrated process development is a necessary method for achieving acceptable process latitude. The application of assist features for rule based OPC requires the simultaneous optimization of the mask, illumination optics and the resist.Described in this paper are the details involved in optimizing each of these aspects for line and space imaging.A reference pitch is first chosen to determine how the optics will be set. The ideal sigma setting is determined by a simple geometrically derived expression. The inner and outer machine settings are determined, in turn,with the simulation of a figure of merit. The maximum value of the response surface of this FOM occurs at the optimal sigma settings. Experimental confirmation of this is shown in the paper.Assist features are used to modify the aerial image of the more isolated images on the mask. The effect that the diffraction of the scattering bars (SBs) has on the image intensity distribution is explained. Rules for determining the size and placement of SBs are also given.Resist is optimized for use with off-axis illumination and assist features. A general explanation of the material' s effect is discussed along with the affect on the through-pitch bias. The paper culminates with the showing of the lithographic results from the fully optimized system.     

Cost-effective test solutions for smart card and other integrated flash applications

From its emergence in the late 1980s as a lower cost alternative to early EEPROM technologies, flash memory has evolved to higher densities and speedsand rapidly growing acceptance in mobile applications.In the process, flash memory devices have placed increased test requirements on manufacturers. Today, as flash device test grows in importance in China, manufacturers face growing pressure for reduced cost-oftest, increased throughput and greater return on investment for test equipment. At the same time, the move to integrated flash packages for contactless smart card applications adds a significant further challenge to manufacturers seeking rapid, low-cost test.     

Theoretical analysis of the relationship between the Brillouin gain coefficient and the strain in the optical-fiber sensors

The relation between the power of the Brillouin signal and the strain is one of the bases of the distributed fiber sensors of temperature and strain. The coefficient of the Bfillouin gain can be changed by the temperature and the strain that will affect the power of the Brillouin scattering. The relation between the change of the Brillouin gain coefficient and the strain is thought to be linear by many researchers. However, it is not always linear based on the theoretical analysis and numerical simulation. Therefore, errors will be caused if the relation between the change of the Brillouin gain coefficient and the strain is regarded as to be linear approximately for measuring the temperature and the strain. For this reason, the influence of the parameters on the Brillouin gain coefficient is proposed through theoretical analysis and numerical simulation.     

An improved parallel thinning algorithm with two subiterations

The parallel thinning algorithm with two subiterations is improved in this paper. By analyzing the notions of connected components and passes, a conclusion is drawn that the number of passes and the number of eight-connected components are equal. Then the expression of the number of eight-connected components is obtained which replaces the old one in the algorithm. And a reserving condition is proposed by experiments, which alleviates the excess deletion where a diagonal line and a beeline intersect. The experimental results demonstrate that the thinned curve is almost located in the middle of the original curve connectivelv with single pixel width and the processing speed is high.     

Novel fiber-optical interferometer with miniaturized probe for in-hole measurements

Today, micro-system technology and the development of new MEMS （Micro-Electro-Mechanical Systems） are emerging rapidly. In order for this development to become a success in the long run, measurement systems have to ensure product quality. Most often, MEMS have to be tested by means of functionality or destructive tests. One reason for this is that there are no suitable systems or sensing probes available which can be used for the measurement of quasi inaccessible features like small holes or cavities. We present a measurement system that could be used for these kinds of measurements. The system combines a fiber optical, miniaturized sensing probe with low-coherence interferometry, so that absolute distance measurements with nanometer accuracy are possible.     

Development of the readout system for waveguide multilayer optical card

Waveguide multilayer optical card （WMOC） is a novel storage device of three-dimensional optical information. An advanced readout system fitting for the WMOC is introduced in this paper. The hardware mainly consists of the light source for reading, WMOC, motorized stages addressing unit, microscope imaging unit, CCD detecting unit and PC controlling ＆ processing unit. The movement of the precision motorized stage is controlled by the computer through Visual Basic （VB） language in software. A control panel is also designed to get the layer address and the page address through which the position of the motorized stages can be changed. The WMOC readout system is easy to manage and the readout result is directly displayed on computer monitor.     

Study of waveguide coupling efficiency in hybrid silicon lasers

This paper presents a new method to increase the waveguide coupling efficiency in hybrid silicon lasers. We find that the propagation constant of the InGaAsP emitting layer can be equal to that of the Si resonant layer through improving the design size of the InP waveguide. The coupling power achieves 42% of the total power in the hybrid lasers when the thickness of the bonding layer is 100 nm. Our result is very close to 50% of the total power reported by Intel when the thickness of the thin bonding layer is less than 5 nm. Therefore, our invariable coupling power technique is simpler than Intel＇s.     

Collinear phase-matching study of terahertz-wave generation via difference frequency mixed in GaAs and Inp

The collinearly phase-matching condition of terahertz-wave generation via difference frequency mixed in GaAs and InP is theoretically studied. In collinear phase-matching, the optimum phase-matching wave hands of these two crystals are calculated. The optimum phase-matching wave bands in GaAs and lnP are 0.95-1.38μm and 0.7-0.96μm respectively. The influence of the wavelength choice of the pump wave on the coherent length in THz-wave tuning is also discussed. The influence of the temperature alteration on the phase-matching and the temperature tuning properties in GaAs crystal are calculated and analyzed. It can serve for the following experiments as a theoretical evidence and a reference as well.     

Effects of the alloy compositions on the phonon-polaritons in ternary mixed crystals

Composition dependence of bulk and surface phonon-polaritons in ternary mixed crystals are studied in the framework of the modified random-element-isodisplacement model and the Bom-Huang approximation. The numerical results for Several Ⅱ - Ⅵ and Ⅲ- Ⅴ compound systems are performed, and the polariton frequencies as functions of the compositions for ternary mixed crystals AlxGa1-xAs, GaPxAS1-x, ZnSxSe1-x, GaAsxSb1-x, GaxIn1-xP, and ZnxCd1-xS as examples are given and discussed. The results show that the dependence of the energies of two branches of bulk phonon-polaritons which have phonon-like characteristics, and surface phonon-polaritons on the compositions of ternary mixed crystals are nonlinear and different from those of the corresponding binary systems.     

New insert layer structure OLEDs

An insert layer structure organic electroluminescent device（OLED） based on a new luminescent material （Zn（salen）） is fabricated. The configuration of the device is ITO/CuPc/NPD/Zn（salen）/Liq/LiF/A1/CuPc/NPD/Zn（salen）/Liq/LiF/A1. Effective insert electrode layers comprising LiF（1nm）/Al（5 nm） are used as a single semitransparent mirror, and bilayer cathode LiF（1 nm）/A1（100 nm） is used as a reflecting mirror. The two mirrors form a Fabry-Perot microcavity and two emissive units. The maximum brightness and luminous efficiency reach 674 cd/m^2 and 2.652 cd/A, respectively, which are 2.1 and 3.7 times higher than the conventional device, respectively. The superior brightness and luminous efficiency over conventional single-unit devices are attributed to microcavity effect.