Meyer–Neldel rule in fullerene field-effect transistors

The temperature dependence of the field-effect mobility is investigated in vacuum evaporated C₆₀-based organic field-effect transistors. The results show a thermally activated behavior with an activation energy that depends on the field-induced charge carrier density in the transistor channel. Upon extrapolation of the data in an Arrhenius plot we find an empirical relation, termed the Meyer–Neldel rule, which states that the mobility prefactor increases exponentially with the activation energy. Based on this analysis a characteristic temperature is extracted. The possible implications of this observation in terms of charge transport in fullerene-based field-effect transistors are discussed.     

Electrical characteristics of AlInN/GaN HEMTs under cryogenic operation

Electrical properties of an AlInN/GaN high-electron mobility transistor (HEMT) on a sapphire substrate are investi-gated in a cryogenic temperature range from 295 K down to 50 K. It is shown that drain saturation current and conductance increase as transistor operation temperature decreases. A self-heating effect is observed over the entire range of temperature under high power consumption. The dependence of channel electron mobility on electron density is investigated in detail. It is found that aside from Coulomb scattering, electrons that have been pushed away from the AlInN/GaN interface into the bulk GaN substrate at a large reverse gate voltage are also responsible for the electron mobility drop with the decrease of electron density.     

Degraded model of radiation-induced acceptor defects for GaN-based high electron mobility transistors （HEMTs）

Using depletion approximation theory and introducing acceptor defects which can characterize radiation induced deep-level defects in AlGaN/GaN heterostructures, we set up a radiation damage model of AlGaN/GaN high electron mobility transistor (HEMT) to separately simulate the effects of several main radiation damage mechanisms and the complete radiation damage effect simultaneously considering the degradation in mobility. Our calculated results, consistent with the experimental results, indicate that thin AlGaN barrier layer, high Al content and high doping concentration are favourable for restraining the shifts of threshold voltage in the AlGaN/GaN HEMT; when the acceptor concentration induced is less than 10¹⁴cm^-3, the shifts in threshold voltage are not obvious; only when the acceptor concentration induced is higher than 10¹⁶cm^-3, will the shifts of threshold voltage remarkably increase; the increase of threshold voltage, resulting from radiation induced acceptor, mainly contributes to the degradation in drain saturation current of the current--voltage (I--V) characteristic, but has no effect on the transconductance in the saturation area.     

高跨导氢终端多晶金刚石长沟道场效应晶体管特性研究

基于多晶金刚石制作了栅长为4 pm的铝栅氢终端金刚石场效应晶体管.器件的饱和漏源电流为160 mA/mm,导通电阻低达37.85Ω·mm,最大跨导达到32 mS/mm,且跨导高于最大值的90%的栅压(V_(GS))范围达到3 V(-2 V≤V_(GS)≤-5 V).通过传输线电阻分析以及器件的导通电阻和电容-电压特性分析,发现氢终端多晶金刚石栅下沟道中的空穴面浓度达到了1.56×10~(13)cm~(-2),有效迁移率在前述高跨导栅压范围保持在约170 cm~2/(V·s).分析认为,较低的栅源和栅漏串联电阻、沟道中高密度的载流子和在大范围栅压内的高水平迁移率是引起高而宽阔的跨导峰和低导通电阻的原因.     

太赫兹互补金属氧化物半导体场效应管探测器理论模型中扩散效应研究

针对基于经典动力学理论传统模型中忽略扩散效应的问题,通过对基于玻尔兹曼理论的场效应管传输线模型的理论分析,建立了包含扩散效应的太赫兹互补金属氧化物半导体(CMOS)场效应管探测器理论模型,研究扩散效应对场效应管电导及响应度的影响.同时,将此模型与忽略了扩散效应的传统模型进行了对比仿真模拟,给出了两种模型下的电流响应度随温度及频率变化的差别.依据仿真结果,并结合3σ原则明确了场效应管传输线模型中扩散部分省略的依据和条件.研究结果表明:扩散部分引起的响应度差异大小主要由场效应管的工作温度及工作频率决定.其中工作频率起主要作用,温度变化对差异大小影响较为微弱;而对于工作频率而言,当场效应管工作频率小于1 THz时,模型中的扩散部分可以忽略不计;而当工作频率大于1 THz时,扩散部分不可省略,此时场效应管模型需同时包含漂移、散射及扩散三个物理过程.本文的研究结果为太赫兹CMOS场效应管理论模型的精确建立及模拟提供了理论支持.     

室温下溅射法制备高迁移率氧化锌薄膜晶体管

为降低氧化锌薄膜晶体管(ZnO TFT)的工作电压,提高迁移率,采用磁控溅射法在氧化铟锡(ITO)导电玻璃基底上室温下依次沉积NbLaO栅介质层和ZnO半导体有源层,制备出ZnO TFT,对器件的电特性进行了表征。该ZnO TFT呈现出优异的器件性能:当栅电压为5 V、漏源电压为10 V时,器件的饱和漏电流高达2.2 m A;有效场效应饱和迁移率高达107 cm~2/(V·s),是目前所报道的室温下溅射法制备ZnO TFT的最高值,亚阈值摆幅为0.28 V/decade,开关电流比大于107。利用原子力显微镜(AFM)对NbLaO和ZnO薄膜的表面形貌进行了分析,分析了器件的低频噪声特性,对器件呈现高迁移率、低亚阈值摆幅以及迟滞现象的机理进行了讨论。     

Non-recessed-gate quasi-E-mode double heterojunction AlGaN/GaN high electron mobility transistor with high breakdown voltage

A non-recessed-gate quasi-E-mode double heterojunction AlGaN/GaN high electron mobility transistor(quasi-EDHEMT) with a thin barrier, high breakdown voltage and good performance of drain induced barrier lowering(DIBL)was presented. Due to the metal organic chemical vapor deposition(MOCVD) grown 9-nm undoped AlGaN barrier, the effect that the gate metal depleted the two-dimensiomal electron gas(2DEG) was greatly impressed. Therefore, the density of carriers in the channel was nearly zero. Hence, the threshold voltage was above 0 V. Quasi-E-DHEMT with 4.1-μm source-to-drain distance, 2.6-μm gate-to-drain distance, and 0.5-μm gate length showed a drain current of 260 mA/mm.The threshold voltage of this device was 0.165 V when the drain voltage was 10 V and the DIBL was 5.26 mV/V. The quasi-E-DHEMT drain leakage current at a drain voltage of 146 V and a gate voltage of-6 V was below 1 mA/mm. This indicated that the hard breakdown voltage was more than 146 V.     

Electrothermal simulation of the self-heating effects in 4H-SiC MESFETs

A thermal model of 4H-SiC MESFET is developed based on the temperature dependences of material parameters and three-region $I-V$ model. The static current characteristics of 4H-SiC MESFET have been obtained with the consideration of the self-heating effect on related parameters including electron mobility, saturation velocity and thermal conductivity. High voltage performances are analysed using equivalent thermal conductivity model. Using the physical-based simulations, we studied the dependence of self-heating temperature on the thickness and doping of substrate. The obtained results can be used for optimization of the thermal design of the SiC-based high-power field effect transistors.     

4H-SiC金属-半导体场效应晶体管大信号I-V特性和小信号参数的计算

基于碳化硅金属-半导体场效应晶体管内部载流子输运的物理特性分析,建立适于精确计算4H-SiCMESFET器件大信号电流-电压特性和小信号参数的解析模型.该模型采用场致迁移率、速度饱和近似,并考虑碳化硅中杂质不完全离化效应及漏源串联电阻的影响,栅偏置为0 V时,获得最大跨导约为48 mS·mm^-1.计算结果与实验数据有很好的一致性.该模型具有物理概念清晰且计算较为准确的优点,适于SiC器件以及电路研究使用.     

有机场效应晶体管的非线性注入模型

有机场效应晶体管(Organic field effect transistor,OFET)的非线性特性是指其输出特性曲线在较低的漏极电压下出现类似于二极管的电压电流特性曲线,这种现象在有机场效应晶体管的实验研究中极为常见。Simonetti等通过引入随栅极电压变化的迁移率提出了模型并成功解释了这一现象,但实验中从器件转移特性得出的迁移率通常与栅极电压无关。本文通过引入常数迁移率对该模型进行改进,运用改进的模型研究了影响OFET非线性特性的主要因素,并对如何更加准确地获得器件参数进行了探究。     

Continuous tuning of the threshold voltage of organic thin-film transistors by a chemically reactive interfacial layer

For the design and manufacture of complex integrated circuits, control over the threshold voltage of the transistors is essential. In the present contribution, we present a non-invasive method to tune the threshold voltage of organic thin-film transistors after device assembly over a wide range without any significant degradation of the device characteristics. This is realized by incorporating a thin, chemically reactive siloxane layer bonded to the gate oxide. This results in threshold voltages of around 70 V in the as-prepared devices. By exposing a transistor modified in this way to ammonia at different concentrations, the threshold voltage can be tuned in steps of only a few volts. This treatment affects only the charge density at the semiconductor–dielectric interface, leaving the overall shape of the transistor characteristics and the charge-carrier mobility largely unaltered.     

AlGaN/GaN双异质结F注入增强型高电子迁移率晶体管

理论模拟了不同GaN沟道厚度的双异质结(AlGaN/GaN/AlGaN/GaN)材料对高电子迁移率晶体管(HEMT)特性的影响,并模拟了不同F注入剂量下用该材料制作的增强型器件的特性差异.采用双异质结材料,结合F注入工艺成功地研制出了较高正向阈值电压的增强型HEMT器件.实验研究了三种GaN沟道厚度制作的增强型器件直流特性的差异,与模拟结果进行了对比验证.采用降低的F注入等离子体功率,减小了等离子体处理工艺对器件沟道迁移率的损伤,研制出的器件未经高温退火即实现了较高的跨导和饱和电流特性.对14 nm GaN沟道厚度的器件进行了阈值电压温度稳定性和栅泄漏电流的比较研究,并且分析了双异质结器件的漏致势垒降低效应.     

高功率微波作用下高电子迁移率晶体管的损伤机理

本文针对高电子迁移率晶体管在高功率微波注入条件下的损伤过程和机理进行了研究,借助SentaurusTCAD仿真软件建立了晶体管的二维电热模型,并仿真了高功率微波注入下的器件响应.探索了器件内部电流密度、电场强度、温度分布以及端电流随微波作用时间的变化规律.研究结果表明,当幅值为20 V,频率为14.9 GHz的微波信号由栅极注入后,器件正半周电流密度远大于负半周电流密度,而负半周电场强度高于正半周电场.在强电场和大电流的共同作用下,器件内部的升温过程同时发生在信号的正、负半周内.又因栅极下靠近源极侧既是电场最强处,也是电流最密集之处,使得温度峰值出现在该处.最后,对微波信号损伤的高电子迁移率晶体管进行表面形貌失效分析,表明仿真与实验结果符合良好.     

Degradation of gate-recessed MOS-HEMTs and conventional HEMTs under DC electrical stress

The performance degradation of gate-recessed metal–oxide–semiconductor high electron mobility transistor(MOSHEMT) is compared with that of conventional high electron mobility transistor(HEMT) under direct current(DC) stress,and the degradation mechanism is studied. Under the channel hot electron injection stress, the degradation of gate-recessed MOS-HEMT is more serious than that of conventional HEMT devices due to the combined effect of traps in the barrier layer, and that under the gate dielectric of the device. The threshold voltage of conventional HEMT shows a reduction under the gate electron injection stress, which is caused by the barrier layer traps trapping the injected electrons and releasing them into the channel. However, because of defects under gate dielectrics which can trap the electrons injected from gate and deplete part of the channel, the threshold voltage of gate-recessed MOS-HEMT first increases and then decreases as the conventional HEMT. The saturation phenomenon of threshold voltage degradation under high field stress verifies the existence of threshold voltage reduction effect caused by gate electron injection.     

A quasi-two-dimensional charge transport model of AlGaN/GaN high electron mobility transistors (HEMTs)

A quasi-two-dimensional charge transport model of AlGaN/GaN high electron mobility transistor has been developed that is capable of accurately predicting the drain current as well as small-signal parameters such as drain conductance and device transconductance. This model built up with incorporation of fully and partially occupied sub-bands in the interface quantum well, combined with a numerically self-consistent solution of the Schrödinger and Poisson equations. In addition, nonlinear polarization effects, self-heating, voltage drops in the ungated regions of the device are also taken into account. Also, to develop the model, the accurate two-dimensional electron gas mobility and the electron drift velocity have been used. The calculated model results are in very good agreement with existing experimental data for Al_mGa_1−mN/GaN HEMT devices with Al mole fraction within the range from 0.15 to 0.50, especially in the linear regime of I–V curve.     

A novel deep submicron SiGe-on-insulator (SGOI) MOSFET with modified channel band energy for electrical performance improvement

In this paper, we present the unique features exhibited by a novel nanoscale SiGe-on-insulator metal-oxide-semiconductor field-effect transistor (MOSFET) with modified channel band energy. The key idea in this work is to modify the band energy in the channel for improving electrical performances. Graded Ge composition profile is employed in the channel that leads to call the proposed structure as GC-SGOI structure. Using two-dimensional two-carrier simulation we demonstrate that the GC-SGOI structure has higher saturation velocity in comparison with stepped (SC-SGOI) and uniform (UC-SGOI) germanium composition due to the high conduction and valence bands slopes by using graded Ge composition profile. Also, our results show that the GC-SGOI exhibit excellent properties not only higher mobility, drain current and saturation velocity but also hot electron degradation improvement and better reliability. Therefore, refer to the results, the GC-SGOI structure has superior performances in comparison with the SC- and UC-SGOI structures which leads to be a good candidate for VLSI circuits.     

基于数据线控制发光的A-IGZO薄膜晶体管集成AMOLED像素电路

本文提出了一种采用铟镓锌氧化物（IGZO）薄膜晶体管（TFT）的有源矩阵有机发光二极管（AMOLED）显示器的新型补偿结构。它利用数据线关闭电源和驱动晶体管之间的控制晶体管,以抑制编程期间的泄漏电流。在所提出的电路和传统电路之间进行电路性能的比较,表明所提出的像素电路可以有效地补偿驱动晶体管的阈值电压偏移和迁移率变化。当V_TH飘移2 V和μ增加30%时,I_OLED误差率可以分别降低至小于5%和9%。此外,由于使用同时驱动方法,因此所需的最小编程时间可以被详细推导出来。所提出的像素电路的编程能力和机制已经通过FPGA平台和离散的场效应器件所证实。尽管所提出的像素电路具有非常简单的驱动结构,但它能够提高补偿精度。     

Electrical properties of an organic memristive system

We present a study on an organic resistive switching device based on the heterojunction of a thin conducting polyaniline (PANI) layer and a ions containing gel (or solution). We have studied the device, characterized by a non-linear and rectifying response to the applied voltage, as a function of some chemical and geometrical parameters such as solution pH, ions concentration and junction contact area, finding out their influence on the device electrical parameters such as the saturation current, the activation voltage, and the response time. The study leads us to develop a physical model of the device and control its response through the fabrication process predicting also interesting properties obtainable with a device miniaturization.     

Nonadiabatic charge pumping in a hybrid single-electron transistor

We study theoretically current quantization in the charge turnstile based on the superconductor-normal-metal single-electron transistor. The quantization accuracy is limited by either Andreev reflection or by Cooper-pair-electron cotunneling. The rates of these processes are calculated in the "above-the-threshold" regime when they compete directly with the lowest-order tunneling. By shaping the ac gate voltage drive it should be possible to achieve the metrological accuracy of 10;{-8}, while maintaining the quantized current on the level of 30 pA, just by one turnstile with realistic parameters using aluminum as a superconductor.     

Amorphous IZO TTFTs with saturation mobilities exceeding 100 cm2/Vs

In this paper we demonstrate the use of amorphous binary In₂O₃–ZnO oxides simultaneously as active channel layer and as source/drain regions in transparent thin film transistor (TTFT), processed at room temperature by rf sputtering. The TTFTs operate in the enhancement mode and their performances are thickness dependent. The best TTFTs exhibit saturation mobilities higher than 10² cm²/Vs, threshold voltages lower than 6 V, gate voltage swing of 0.8 V/dec and an on/off current ratio of 10⁷. This mobility is at least two orders of magnitude higher than that of conventional amorphous silicon TFTs and comparable to or even better than other polycrystalline semiconductors. (© 2007 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)