隐埋层中二维效应对全耗尽SOI非对称HALO结构阈值电压的影响

在非对称HALO结构的全耗尽SOI二维阈值电压解析模型的基础上,对阈值电压受隐埋层中二维效应的影响进行了讨论.通过与一维模型的比较,说明在深亚微米SOI MOSFET器件中隐埋层的二维效应会导致器件提前出现短沟道效应.新模型结果与二维数值模拟软件MEDICI吻合较好.     

Nanoscale FD/SOI CMOS: thick or thin BOX?

The question of buried-oxide (BOX) thickness scaling for nanoscale fully depleted (FD) silicon-on-insulator (SOI) CMOS is addressed via insightful quantitative and qualitative analyses. Whereas, FD/SOI MOSFETs with thin BOX give better control of short-channel effects (SCEs), they complicate the material and/or process technologies and undermine CMOS speed. We show that the improved SCE control afforded by thin BOX is due to high transverse electric field in the body defined by the device asymmetry, and not only to the suppression of electric-field fringing in the BOX as is commonly presumed. Since conventional FD/SOI CMOS with thick BOX can be scaled via ultrathin bodies, we conclude that thin BOX is not needed nor desirable.     

Short-channel effects in SOI MOSFETs

Short-channel effects in thin-film silicon-on-insulator (SOI) MOSFETs are shown to be unique because of dependences on film thickness and body and back-gate (substrate) biases. These dependences enable control of threshold-voltage reduction, channel-charge enhancement due to a drain bias, carrier velocity saturation, channel-length modulation and its effect on output conductance, as well as device degradation due to hot carriers in short-channel SOI MOSFETs. A short-channel effect exclusive to SOI MOSFETs, back-surface charge modulation, is described. Because of the short-channel effects, the use of SOI MOSFETs in VLSI circuits provides the designer with additional flexibility as compared to bulk-MOSFET design. Various design tradeoffs are discussed     

Influences of buried-oxide interface on inversion-layer mobility inultra-thin SOI MOSFETs

This paper reports on a study of the inversion-layer mobility in n-channel Si MOSFETs fabricated on a silicon-on-insulator (SOI) substrate. In order to make clear the influences of the buried-oxide interface on the inversion-layer mobility in ultra-thin film SOI transistors, SOI wafers of different quality at the buried-oxide interface were prepared, and the mobility behaviors were compared quantitatively. The transistors with a relatively thick SOI film exhibited the universal relationship between the effective mobility and the effective normal field, regardless of the buried-oxide interface quality. It was found, however, that Coulomb scattering due to charged centers at the backside interface between SOI films and buried oxides has great influence on the effective mobility in the thin SOI thickness region, depending on the buried-oxide interface quality. This means that Coulomb scattering due to charged centers at the buried-oxide interface can degrade the mobility with decreasing SOI thickness, unless the SOI wafer quality at the buried-oxide interface is controlled carefully     

Two-dimensional analytic modeling of very thin SOI MOSFETs

An analytic solution of the Poisson's equation for MOSFETs on very thin SOI (silicon on insulator) was developed using an infinite series method. The calculation region includes the thin SOI and the gate and buried oxides. The results of this model were found to agree well with a two-dimensional (PISCES) simulation in the subthreshold region and the linear region with small V_DS. This model is used to study the short-channel behavior of very small MOS transistors on thin SOI. It is found that with very thin SOI, short-channel effects are much reduced compared to bulk MOS transistors and depend on the bulk-substrate bias. The model also shows that it is possible to fabricate submicrometer transistors on very thin SOI even if the channel doping is nearly intrinsic     

Analysis of Self-Heating Effects in Ultrathin-Body SOI MOSFETs by Device Simulation

This paper discusses self-heating (SHE) effects in silicon-on-insulator (SOI) CMOS technology and applies device simulation to analyze the impact of thermal effects on the operation of nanoscale SOI n-MOSFETs. A 2-D drift-diffusion electrothermal simulation, using an electron transport model calibrated against Monte Carlo simulations at various temperatures, is employed in the analysis. We report the effects of device-structure parameters, such as SOI layer thickness, buried-oxide (BOX) thickness, source/drain (S/D) extension length, and thickness of the elevated S/D region, on the SHE of nanoscale MOSFETs. The SHE effects become significant due to the adoption of thin silicon layers and to the low thermal conductivity of the BOX, leading to the rise of large temperature under nominal operation conditions for high-performance digital circuits. The ac performance of SOI MOSFETs is influenced as well, and in particular, a severe degradation of the cutoff frequency of very short MOSFETs is predicted by numerical electrothermal device simulations. Although the effects of SHE on device performance are found to be somewhat modest and might be mitigated through device design, they may result in a degradation of the long-term reliability.     

Analytical modeling of the two-dimensional potential distribution and threshold voltage of the SOI four-gate transistor

The two-dimensional (2-D) channel potential and threshold voltage of the silicon-on-insulator (SOI) four-gate transistor (G/sup 4/-FET) are modeled. The 2-D analytical body potential is derived by assuming a parabolic potential variation between the lateral junction-gates and by solving Poisson's equation. The model is used to obtain the surface threshold voltage of the G/sup 4/-FET as a function of the lateral gate bias and for all possible charge conditions at the back interface. The body-potential model is extendable to fully depleted SOI MOSFETs and can serve to depict the charge-sharing and drain-induced barrier-lowering effects in short-channel devices.     

Quantum-mechanical suppression and enhancement of SCEs in ultrathin SOI MOSFETs

This paper simulates the transport characteristics of ultrathin silicon-on-insulator MOSFETs, and evaluates the influence of the quantum-mechanical mechanism on the short-channel effects on the basis of the density-gradient model. It is clearly shown that the quantum-mechanical mechanism suppresses the buried-insulator-induced barrier lowering with regard to the subthreshold swing because the surface dark space yields a high-field region in the source region adjacent to the channel. It is also suggested that the quantum-mechanical mechanism enhances the impact of the apparent charge-sharing effect on the threshold voltage because the surface dark space effectively increases the thickness of the gate-oxide layer and buried-oxide layer.     

Dual-gate operation and volume inversion in n-channel SOI MOSFET's

The effects of volume inversion in thin-film short-channel SOI MOSFETs and the efficacy of dual-gate operation in enhancing their device performance have been analyzed using two-dimensional device simulations and one-dimensional analytical computations. The analyses have been restricted to the strong inversion regime, which is the practically useful region of operation of the SOI MOSFETs. In this region, the analyses suggest that when compared at constant V _G-V_T values, the dual-channel volume inverted devices do not offer significant current-enhancement advantage, other than that expected from the second channel, over the conventional single-channel devices for silicon thicknesses in the 0.1-μm range     

Three mechanisms determining short-channel effects infully-depleted SOI MOSFETs

Mechanisms determining short-channel effects (SCE) in fully-depleted (FD) SOI MOSFETs are clarified based on experimental results of threshold voltage (V_T) dependence upon gate length, and analysis using a two-dimensional (2-D) device simulator. Drain-induced barrier lowering (DIBL) effect is a well known mechanism which determines the SCE in conventional bulk MOSFETs. In FDMOSFETs, two more peculiar and important mechanisms are found out, i.e., the accumulation of majority carriers in the body region generated by impact ionization, and the DIBL effect on the barrier height for majority carriers at the edge of the source near the bottom of the body. Due to these peculiar mechanisms, V_T dependence upon gate length in the short-channel region is weakened. It is also shown that floating body effects, the scatter of V_T, and transient phenomena are suppressed due to the SCE peculiar to FD MOSFETs     

A Review of Core Compact Models for Undoped Double-Gate SOI MOSFETs

In this paper, we review the compact-modeling framework for undoped double-gate (DG) silicon-on-insulator (SOI) MOSFETs. The use of multiple gates has emerged as a new technology to possibly replace the conventional planar MOSFET when its feature size is scaled to the sub-50-nm regime. MOSFET technology has been the choice for mainstream digital circuits for very large scale integration as well as for other high-frequency applications in the low-gigahertz range. But the continuing scaling of MOSFET presents many challenges, and multiple-gate, particularly DG, SOI devices seem to be attractive alternatives as they can effectively reduce the short-channel effects and yield higher current drive. Core compact models, including the analysis for surface potential and drain-current, for both the symmetric and asymmetric DG SOI MOSFETs, are discussed and compared. Numerical simulations are also included in order to assess the validity of the models reviewed     

SOI thermal impedance extraction methodology and its significancefor circuit simulation

The buried-oxide in SOI MOSFET inhibits heat dissipation in the Si film and leads to increase in transistor temperature. This paper reports a simple and accurate characterization method for the self-heating effect (SHE) in SOI MOSFETs. The AC output conductance at a chosen bias point is measured at several frequencies to determine the thermal resistance (R_th) and thermal capacitance (C_th) associated with the SOI device. This methodology is important to remove the misleadingly large self-heating effect from the DC I-V data in device modeling. Not correcting for SHE may lead to significant error in circuit simulation. After SHE is accounted for, the frequency-dependent SHE may be disabled in circuit simulation without sacrificing the accuracy, thus providing faster circuit simulation for high-frequency circuits     

The enhancement of gate-induced-drain-leakage (GIDL) current inshort-channel SOI MOSFET and its application in measuring lateralbipolar current gain β

An off-state leakage current unique for short-channel SOI MOSFETs is reported. This off-state leakage is the amplification of gate-induced-drain-leakage current by the lateral bipolar transistor in an SOI device due to the floating body. The leakage current can be enhanced by as much as 100 times for 1/4 μm SOI devices. This can pose severe constraints in future 0.1 μm SOI device design. A novel technique was developed based on this mechanism to measure the lateral bipolar transistor current gain β of SOI devices without using a body contact     

Design guideline for minimum channel length in silicon-on-insulator (SOI) MOSFET

This brief proposes a preliminary design guideline for the minimum channel length in silicon-on-insulator (SOI) MOSFETs that is based on simulations of device characteristics. The simulations examine a wide variation in many device parameters to comprehensively evaluate device characteristics. A characteristic parameter that can successfully describe the minimum channel length is found. It is suggested that a sub-20-nm-channel single-gate SOI MOSFET with suppressed short-channel effects can be stably realized by optimizing its device parameters.     

Fabrication of 50-nm gate SOI n-MOSFETs using novel plasma-doping technique

A plasma-doping technique for fabricating nanoscale silicon-on-insulator (SOI) MOSFETs has been investigated. The source/drain (S/D) extensions of the tri-gate structure SOI n-MOSFETs were formed by using an elevated temperature plasma-doping method. Even though the activation annealing after plasma doping was excluded to minimize the diffusion of dopants, which resulted in a laterally abrupt S/D junction, we obtained a low sheet resistance of 920 /spl Omega///spl square/ by the elevated temperature plasma doping of 527 /spl deg/C. A tri-gate structure silicon-on-insulator n-MOSFET with a gate length of 50 nm was successfully fabricated and revealed suppressed short-channel effects.     

超高速CMOS/SOI51级环振电路的研制

利用CMOS/SOI工艺在4英寸SIMOX材料上成功制备出沟道长度为1μm、器件性能良好的CMOS/SOI部分耗尽器件和电路,从单管的开关电流比看,电路可以实现较高速度性能的同时又可以有效抑制泄漏电流.所研制的51级CMOS/SOI环振电路表现出优越的高速度性能,5V电源电压下单门延迟时间达到92ps,同时可工作的电源电压范围较宽,说明CMOS/SOI技术在器件尺寸降低后将表现出比体硅更具吸引力的应用前景.     

An assessment of single-electron effects in multiple-gate SOI MOSFETs with 1.6-nm gate oxide near room temperature

This letter provides an assessment of single-electron effects in ultrashort multiple-gate silicon-on-insulator (SOI) MOSFETs with 1.6-nm gate oxide. Coulomb blockade oscillations have been observed at room temperature for gate bias as low as 0.2 V. The charging energy, which is about 17 meV for devices with 30-nm gate length, may be modulated by the gate geometry. The multiple-gate SOI MOSFET, with its main advantage in the suppression of short-channel effects for CMOS scaling, presents a very promising scheme to build room-temperature single-electron transistors with standard silicon nanoelectronics process.     

Reliable tantalum-gate fully-depleted-SOI MOSFET technologyfeaturing low-temperature processing

A reliable tantalum (Ta)-gate device technology, which can drastically reduce the number of process steps, has been developed. Ta-gate fully-depleted-silicon-on-insulator (FDSOI) MOSFETs with 0.15-μm gate length by low-temperature processing below 500°C after the gate oxide formation have good on/off characteristics. Comprehensive design guidelines for Ta-gate MOSFETs in the deep-submicrometer regime is provided by investigating a wide range of performance and reliability constraints on the process temperature and the SOI thickness. In the guideline, the recrystallization of the source/drain region gives inferior limits of the SOI thickness and the process temperature. Thermal reaction between Ta and SiO₂ films sets a superior limit of the process temperature, and a short-channel effect sets a superior limit of the SOI thickness     

Threshold voltage model for deep-submicron fully depleted SOI MOSFETs with back gate substrate induced surface potential effects

A simple analytical threshold voltage model for short-channel fully depleted SOI MOSFETs has been derived. The model is based on the analytical solution of the two-dimensional potential distribution in the silicon film (front silicon), which is taken as the sum of the long-channel solution to the Poisson's equation and the short-channel solution to the Laplace equation, and the solution of the Poisson's equation in the silicon substrate (back silicon). The proposed model accounts for the effects of the back gate substrate induced surface potential at the buried oxide-substrate interface which contributed an additional 15–30% reduction in the threshold voltage for the devices used in this work. Conditions on the back gate supply voltage range are determined upon which the surface potential at the buried oxide-substrate interface is accumulated, depleted, or inverted. The short-channel associated drain induced barrier lowering effects are also included in the model. The model predications are in close agreement with PISCES simulation results. The equivalence between the present model and previously reported models is proven. The proposed model is suitable for use in circuit simulation tools such as Spice.