考虑量子效应的短沟道MOSFET二维阈值电压模型

通过数值方法求解泊松方程和薛定谔方程的自洽解，提出了考虑量子效应时不同于经典理论的阈值条件，并得出了精确的一维阈值电压模型，模拟结果与实验十分符合.在此基础上，基于准二维泊松方程，通过考虑短沟道效应和量子效应，建立了较为精确的适合于小尺寸MOSFET的量子修正阈值电压模型,模型同样适用于(超)深亚微米高k栅介质MOSFET电特性的模拟和结构参数的设计. 关键词： 阈值电压 量子效应 短沟道效应 高k栅介质     

小尺寸应变Si金属氧化物半导体场效应晶体管栅隧穿电流预测模型

小尺寸金属氧化物半导体场效应晶体管(MOSFET)器件由于具有超薄的氧化层、关态栅隧穿漏电流的存在严重地影响了器件的性能,应变硅MOSFET器件也存在同样的问题.为了说明漏电流对新型应变硅器件性能的影响,文中利用积分方法从准二维表面势分析开始,提出了小尺寸应变硅MOSFET栅隧穿电流的理论预测模型,并在此基础上使用二维器件仿真软件ISE进行了仔细的比对研究,定量分析了在不同栅压、栅氧化层厚度下MOSFET器件的性能.仿真结果很好地与理论分析相符合,为超大规模集成电路的设计提供了有价值的参考. 关键词： 应变硅 准二维表面势 栅隧穿电流 预测模型     

超薄栅氧化层n-MOSFET软击穿后的导电机制

研究了恒压应力下超薄栅氧化层n型金属-氧化物-半导体场效应晶体管（n-MOSFET）软击穿 后的导电机制.发现在一定的栅电压V_g范围内，软击穿后的栅电流I_g符合Fowl er-Nordheim隧穿公式，但室温下隧穿势垒_b的平均值仅为0936eV，远小于S i/Si O₂界面的势垒高度315eV.研究表明，软击穿后，处于Si/SiO₂界 面量子化能级上的 电子不隧穿到氧化层的导带，而是隧穿到氧化层内的缺陷带上._b与缺陷带能 级和电 子所处的量子能级相关；高温下，激发态电子对隧穿电流贡献的增大导致_b逐 渐降低. 关键词： 软击穿 栅电流 类Fowler-Nordheim隧穿 超薄栅氧化层     

单轴应变硅nMOSFET栅隧穿电流模型

本文基于量子机制建立了单轴应变硅nMOSFET栅隧穿电流模型,分析了隧穿电流与器件结构参数、偏置电压及应力的关系.仿真分析结果与单轴应变硅nMOSFET的实验结果符合较好,表明该模型可行.同时与具有相同条件的双轴应变硅nMOSFET的实验结果相比,隧穿电流更小,从而表明单轴应变硅器件更具有优势.该模型物理机理明确,不仅适用于单轴应变硅nMOSFET,只要将相关的参数置换,该模型也同样适用于单轴应变硅pMOSFETs. 关键词： 单轴应变 nMOSFET 栅隧穿电流 模型     

部分耗尽结构绝缘体上硅器件的低频噪声特性

针对部分耗尽结构绝缘体上硅(silicon-on-insulator, SOI)器件低频噪声特性展开实验与理论研究. 实验结果表明, 器件低频噪声主要来源于SiO₂-Si界面附近缺陷态对载流子的俘获与释放过程; 基于此理论可提取前栅和背栅氧化层界面附近缺陷态密度分别为8×10¹⁷ eV^-1·cm^-3和2.76×10¹⁷ eV^-1·cm^-3. 基于电荷隧穿机理, 在考虑隧穿削弱因子、隧穿距离与时间常数之间关系的基础上, 提取了前、背栅氧化层内缺陷态密度随空间的分布情况. 此外, SOI器件沟道电流归一化噪声功率谱密度随沟道长度的增加而线性减小, 这表明器件低频噪声主要来源于沟道的闪烁噪声. 最后, 基于电荷耦合效应, 分析了背栅电压对前栅阈值电压、沟道电流以及沟道电流噪声功率谱密度的影响.     

Snapback应力引起的90 nm NMOSFET's栅氧化层损伤研究

实验结果发现突发击穿(snapback)，偏置下雪崩热空穴注入NMOSFET栅氧化层，产生界面态，同时空穴会陷落在氧化层中.由于栅氧化层很薄，陷落的空穴会与隧穿入氧化层中的电子复合形成大量中性电子陷阱，使得栅隧穿电流不断增大.这些氧化层电子陷阱俘获电子后带负电，引起阈值电压增大、亚阈值电流减小.关态漏泄漏电流的退化分两个阶段：第一阶段亚阈值电流是主要成分，第二阶段栅电流是主要成分.在预加热电子(HE)应力后，HE产生的界面陷阱在snapback应力期间可以屏蔽雪崩热空穴注入栅氧化层，使器件snapback开态和关态特性退化变小. 关键词： 突发击穿 软击穿 应力引起的泄漏电流 热电子应力     

电压应力下超薄栅氧化层n-MOSFET的击穿特性

研究了90nm工艺下栅氧化层厚度为1.4nm的n-MOSFET的击穿特性，包括V-ramp(斜坡电压)应力下器件栅电流模型和CVS(恒定电压应力)下的TDDB(经时击穿)特性，分析了电压应力下器件的失效和退化机理.发现器件的栅电流不是由单一的隧穿引起，同时还有电子的翻越和渗透.在电压应力下，SiO₂中形成的缺陷不仅降低了SiO₂的势垒高度，而且等效减小了SiO₂的厚度(势垒宽度).另外，每一个缺陷都会形成一个导电通道，这些导电通道的形成增大了栅电流，导致器件性能的退化，同时栅击穿时间变长. 关键词： 超薄栅氧化层 斜坡电压 经时击穿 渗透     

钙钛矿结构Pr1－xCaxMnO3薄膜中电脉冲诱导电阻值变化的理论研究

建立一个有效的三明治隧穿模型研究在Pr_1-xCa_xMnO₃薄膜中电流脉冲引起的电阻改变(EPIR)性质，发现载流子在三明治结构各区域间的隧穿概率以及在不均匀界面层的导通概率对材料的EPIR值产生重要影响.还研究了电流-电压曲线中的迟滞效应，得到的结果与近年来的文献报道一致. 关键词： 强关联电子系统 金属-氧化物界面 隧穿     

一个圆柱形双栅场效应晶体管的物理模型

圆柱形双栅场效应晶体管(CSDG MOSFET)是在围栅MOSFET器件增加内部控制栅而形成,与双栅、三栅及围栅MOSFET器件相比,圆柱形双栅MOSFET提供了更好的栅控性能和输出特性.本文通过求解圆柱坐标系下的二维泊松方程,得到了圆柱形双栅MOSFET的电势模型;进一步对反型电荷沿沟道积分,建立其漏源电流模型.分析讨论了圆柱形双栅MOSFET器件的电学特性,结果表明:圆柱形双栅MOSFET外栅沿沟道的最小表面势和器件的阈值电压随栅介质层介电常数的增大而减小,其漏源电流和跨导随栅介质层介电常数的增大而增大;随着器件参数的等比例缩小,沟道反型电荷密度减小,其漏源电流和跨导也减小.     

高k栅介质对肖特基源漏超薄体SOI MOSFET性能的影响

研究了高k栅介质对肖特基源漏超薄体SOI MOSFET性能的影响.随着栅介质介电常数增大,肖特基源漏(SBSD) SOI MOSFET的开态电流减小,这表明边缘感应势垒降低效应(FIBL)并不是对势垒产生影响的主要机理.源端附近边缘感应势垒屏蔽效应(FIBS)是SBSD SOI MOSFET开态电流减小的主要原因.同时还发现,源漏与栅是否对准,高k栅介质对器件性能的影响也不相同.如果源漏与栅交叠,高k栅介质与硅衬底之间加入过渡层可以有效地抑制FIBS效应.如果源漏偏离栅,采用高k侧墙并结合堆叠栅结构,可以提高驱动电流.分析结果表明,来自栅极的电力线在介电常数不同的材料界面发生两次折射.根据结构参数的不同可以调节电力线的疏密,从而达到改变势垒高度,调节驱动电流的目的. 关键词： k栅介质')" href="#">高k栅介质 肖特基源漏(SBSD) 边缘感应势垒屏蔽(FIBS) 绝缘衬底上的硅(SOI)     

Mismatch of dielectric constants at the interface of nanometer metal-oxide-semiconductor devices with high-<Emphasis Type="Italic">K</Emphasis> gate dielectric impacts on the inversion charge density

The comparison of the inversion electron density between a nanometer metal-oxide-semiconductor (MOS) device with high-K gate dielectric and a SiO₂ MOS device with the same equivalent oxide thickness has been discussed. A fully self-consistent solution of the coupled Schr?dinger–Poisson equations demonstrates that a larger dielectric-constant mismatch between the gate dielectric and silicon substrate can reduce electron density in the channel of a MOS device under inversion bias. Such a reduction in inversion electron density of the channel will increase with increase in gate voltage. A reduction in the charge density implies a reduction in the inversion electron density in the channel of a MOS device. It also implies that a larger dielectric constant of the gate dielectric might result in a reduction in the source–drain current and the gate leakage current.     

Interface engineering with an MOCVD grown ZnO interface passivation layer for ZrO2-GaAs metal-oxide-semiconductor devices

This work deals with the fabrication of a GaAs metal-oxide-semiconductor device with an unpinned interface environment. An ultrathin (∼2 nm) interface passivation layer (IPL) of ZnO on GaAs was grown by metal organic chemical vapor deposition to control the interface trap densities and to prevent the Fermi level pinning before high-k deposition. X-ray photoelectron spectroscopy and high resolution transmission electron microscopy results show that an ultra thin layer of ZnO IPL can effectively suppress the oxides formation and minimize the Fermi level pinning at the interface between the GaAs and ZrO₂. By incorporating ZnO IPL, GaAs MOS devices with improved capacitance-voltage and reduced gate leakage current were achieved. The charge trapping behavior of the ZrO₂/ZnO gate stack under constant voltage stressing exhibits an improved interface quality and high dielectric reliability.     

Key technologies for dual high-k and dual metal gate integration

The key technologies for the dual high-k and dual metal gate, such as the electrical optimization of metal insert poly-Si stack structure, the separating of high-k and metal gate of n/pMOS in different regions of the wafer, and the synchronous etching of n/pMOS gate stack, are successfully developed. First, reasonable flat-band voltage and equivalent oxide thickness of pMOS MIPS structure are obtained by further optimizing the HfSiAlON dielectric through incorporating more Al-O dipole at interface between HfSiAlON and bottom SiO_x. Then, the separating of high-k and metal gate for n/pMOS is achieved by SC1(NH_4OH:H_2O_2:H_2O = 1 : 1 : 5) and DHF-based solution for the selective removing of n MOS TaN and Hf Si ON and by BCl_3-based plasma and DHF-based solution for the selective removing of pMOS TaN/Mo and HfSiAlON.After that, the synchronous etching of n/pMOS gate stack is developed by utilizing optimized BCl_3/SF_6/O_2/Ar plasma to obtain a vertical profile for TaN and TaN/Mo and by utilizing BCl_3/Ar plasma combined with DHF-based solution to achieve high selectivity to Si substrate. Finally, good electrical characteristics of CMOS devices, obtained by utilizing these new developed technologies, further confirm that they are practicable technologies for DHDMG integration.     

CVD-derived Hf-based High-k Gate Dielectrics

Hf-based high-k gate dielectric has been recently highlighted as the most promising high-k dielectrics for the next-generation CMOS devices with high performance due to its excellent thermal stability and relatively high dielectric constant. This article provides a comprehensive view of the state-of-the-art research activities in advanced Hf-based high-k gate dielectrics grown by chemical-vapor-deposition-based method, including metal-organic-chemical-vapor-deposition (MOCVD), atomic-layer-chemical-vapor-deposition (ALCVD), and plasma-enhanced- chemical-vapor-deposition (PECVD), in CMOS device. We begin with a survey of methods developed for generating Hf-based high-k gate dielectrics. After that, most attention has been paid to the detailed discussion of the latest development of novel Hf-based high-k gate dielectrics grown by CVD. Finally, we conclude this review with the perspectives and outlook on the future developments in this area. This article explores the possible influences of research breakthroughs of Hf-based gate dielectrics on the current and future applications for nano-MOSFET devices.     

高k介质在新型半导体器件中的应用

当CMOS器件特征尺寸缩小到45 nm以下, SiO₂作为栅介质材料已经无法满足性能和功耗的需要, 用高 k材料替代SiO₂是必然选择. 然而, 由于高 k材料自身存在局限性, 且与器件其他部分的兼容性差, 产生了很多新的问题如界面特性差、 阈值电压增大、 迁移率降低等. 本文简要回顾了高 k栅介质在平面型硅基器件中应用存在的问题以及从材料、 结构和工艺等方面采取的解决措施, 重点介绍了高k材料在新型半导体器件中的应用, 并展望了未来的发展趋势.     

Silicon electro-optic modulator with high-permittivity gate dielectric layer

A high-permittivity （high-k） material is applied as the gate dielectric layer in a silicon metal-oxide- semiconductor （MOS） capacitor to form a special electro-optic （EO） modulator. Both induced charge density and modulation efficiency in the proposed modulator are improved due to the special structure design and the application of the high-k material. The device has an ultra-compact dimension of 691 μm in length.     

Synthesis,characterization and radiation damage studies of high-k dielectric (HfO2) films for MOS device applications

The current trend in miniaturization of metal oxide semiconductor devices needs high-k dielectric materials as gate dielectrics. Among all the high-k dielectric materials, HfO₂ enticed the most attention, and it has already been introduced as a new gate dielectric by the semiconductor industry. High dielectric constant (HfO₂) films (10?nm) were deposited on Si substrates using the e-beam evaporation technique. These samples were characterized by various structural and electrical characterization techniques. Rutherford backscattering spectrometry, X-ray reflectivity, and energy-dispersive X-ray analysis measurements were performed to determine the thickness and stoichiometry of these films. The results obtained from various measurements are found to be consistent with each other. These samples were further characterized by I–V (leakage current) and C–V measurements after depositing suitable metal contacts. A significant decrease in the leakage current and the corresponding increase in device capacitance are observed when these samples were annealed in oxygen atmosphere. Furthermore, we have studied the influence of gamma irradiation on the electrical properties of these films as a function of the irradiation dose. The observed increase in the leakage current accompanied by changes in various other parameters, such as accumulation capacitance, inversion capacitance, flat band voltage, mid-gap voltage, etc., indicates the presence of various types of defects in irradiated samples.     

Implementation of nanoscale circuits using dual metal gate engineered nanowire MOSFET with high-k dielectrics for low power applications

This work covers the impact of dual metal gate engineered Junctionless MOSFET with various high-k dielectric in Nanoscale circuits for low power applications. Due to gate engineering in junctionless MOSFET, graded potential is obtained and results in higher electron velocity of about 31% for HfO₂ than SiO₂ in the channel region, which in turn improves the carrier transport efficiency. The simulation is done using sentaurus TCAD, ON current, OFF current, I_ON/I_OFF ratio, DIBL, gain, transconductance and transconductance generation factor parameters are analysed. When using HfO₂, DIBL shows a reduction of 61.5% over SiO₂. The transconductance and transconductance generation factor shows an improvement of 44% and 35% respectively. The gain and output resistance also shows considerable improvement with high-k dielectrics. Using this device, inverter circuit is implemented with different high-k dielectric material and delay have been decreased by 4% with HfO₂ when compared to SiO₂. In addition, a significant reduction in power dissipation of the inverter circuit is obtained with high-k dielectric Dual Metal Surround Gate Junctionless Transistor than SiO₂ based device. From the analysis, it is found that HfO₂ will be a better alternative for the future nanoscale device.     

Temperature-dependent current conduction mechanism and charge trapping in Ta2O5 RF-sputtered on GaN

A gallium nitride (GaN) based Metal-Oxide-Semiconductor (MOS) capacitor was fabricated using radio frequency (RF)-sputtered tantalum oxide (Ta₂O₅) as the high-k gate dielectric. Electrical characteristics of this capacitor were evaluated via capacitance–voltage (C–V), current–voltage (I–V), and interface trap density (D_it) measurements with emphasis on the substrate temperature dependence ranging from 25 °C to 200 °C. Charge trapping and conduction mechanism in Ta₂O₅ were investigated. The experimental results suggested that higher substrate temperature rendered higher oxide capacitance, reduced gate leakage current, and lowered mid-gap interface trap density at the expenses of high border traps and high fixed oxide charges. The gate leakage current through Ta₂O₅ was found to obey the Ohm's conduction at lower gate bias and the Poole–Frenkel conduction at higher gate bias.