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.     

Single-transistor latch in SOI MOSFETs

A single-transistor latch phenomenon observed in silicon-on-insulator (SOI) MOSFETs is reported. This latch effect, which occurs at high drain biases, is an extreme case of floating-body effects which are present in SOI MOSFETs. The floating body results in positive feedback between the impact ionization current, body-to-source diode forward bias, and transistor currents. At large drain voltages, this positive feedback can maintain a high-drain-to-source current even when the MOS gate is biased well below its threshold voltage     

A method for the prediction of hot-carrier lifetime in floating SOINMOSFETs

A concept was presented for the prediction of the device lifetimes for the hot-carrier effect (hot-carrier lifetimes) in floating SOI MOSFETs. The concept is that hot-carrier lifetimes in floating SOI MOSFETs can be predicted by estimating the hole current. In order to verify the validity of this concept, the hole current was investigated using device simulation. The results showed that the ratio of the hole current to the drain current in a floating-body SOI MOSFET is approximately equal to the ratio of substrate current to drain current in a body-tied one. Based on this fact, a method for accurately predicting the hot-carrier lifetime in floating-body SOI MOSFETs was proposed. The hot-carrier lifetime predicted with this method agreed well with the experimental results. This study showed that only the drain current difference between floating and body-tied structures results in lifetime differences, and there is no special effect on hot-carrier degradation in floating SOI MOSFETs. In this prediction, therefore, floating SOI MOSFETs can be treated in the same way as bulk MOSFETs. Hot-carrier lifetimes in floating SOI MOSFETs can be predicted using the hole current, while substrate currents are used in bulk MOSFETs     

High performance fully-depleted tri-gate CMOS transistors

Fully-depleted (FD) tri-gate CMOS transistors with 60 nm physical gate lengths on SOI substrates have been fabricated. These devices consist of a top and two side gates on an insulating layer. The transistors show near-ideal subthreshold gradient and excellent DIBL behavior, and have drive current characteristics greater than any non-planar devices reported so far, for correctly-targeted threshold voltages. The tri-gate devices also demonstrate full depletion at silicon body dimensions approximately 1.5 - 2 times greater than either single gate SOI or non-planar double-gate SOI for similar gate lengths, indicating that these devices are easier to fabricate using the conventional fabrication tools. Comparing tri-gate transistors to conventional bulk CMOS device at the same technology node, these non-planar devices are found to be competitive with similarly-sized bulk CMOS transistors. Furthermore, three-dimensional (3-D) simulations of tri-gate transistors with transistor gate lengths down to 30 nm show that the 30 nm tri-gate device remains fully depleted, with near-ideal subthreshold swing and excellent short channel characteristics, suggesting that the tri-gate transistor could pose a viable alternative to bulk transistors in the near future.     

Gate-induced floating body effect excess noise in partially depleted SOI MOSFETs

Low frequency excess noise associated to gate-induced floating body effect is for the first time reported in Partially Depleted SOI MOSFETs with ultrathin gate oxide. This was investigated with respect to floating body devices biased in linear regime. Due to a body charging from the gate, a Lorentzian-like noise component superimposes to the conventional 1/f noise spectrum. This excess noise exhibits the same behavior as the Kink-related excess noise previously observed in Partially Depleted devices in saturation regime.     

A temperature-dependent SOI MOSFET model for high-temperatureapplication (27 °C-300 °C)

A temperature-dependent model for long-channel silicon-on-insulator (SOI) MOSFETs for use in the temperature range 27 °C-300 °C, suitable for circuit simulators such as SPICE, is presented. The model physically accounts for the temperature-dependent effects in SOI MOSFETs (such as threshold-voltage reduction, increase of leakage current, decrease of generation due to impact ionization, and channel mobility degradation with increase of temperature) which are influenced by the uniqueness of SOI device structure, i.e. the back gate and the floating film body. The model is verified by the good agreement of the simulations with the experimental data. The model is implemented in SPICE2 to be used for circuit and device CAD. Simple SOI CMOS circuits are successfully simulated at different temperatures     

Design of single-gate n-channel and p-channel MOSFETs with enhanced current-drive due to simultaneous switching of front and back channels in SOI CMOS technology

In this paper, we show that when single gate SOI MOSFETs are biased at a particular ideal back gate voltage, the front and back channels can be turned ON and OFF simultaneously using the front gate voltage, thereby enhancing the current drive of the device. It is shown by analytical models as well as 2-D numerical simulation that both maximum transconductance and minimum subthreshold slope are obtained for this ideal back gate bias. Subsequently, n-channel and p-channel MOSFETs are designed for a conventional SOI CMOS process, where both the front and back channels of these devices turn ON and OFF simultaneously resulting in enhanced current drive and superior performance. The design has been carried out with the help of analytical formulation and verified using the 2-D Device Simulator MEDICI.     

SOI反偏肖特基势垒动态阈值MOS特性

将Ti硅化物-p型体区形成的反偏肖特基势垒结构引入绝缘体上硅动态阈值晶体管.传统栅体直接连接DTMOS,为了避免体源二极管的正向开启,工作电压应当低于0.7V.而采用反偏肖特基势垒结构,DTMOS的工作电压可以拓展到0.7V以上.实验结果显示,室温下采用反偏肖特基势垒SOI DTMOS结构,阈值电压可以动态减小200mV.反偏肖特基势垒SOI DTMOS结构相比于传统模式,显示出优秀的亚阈值特性和电流驱动能力.另外,对浮体SOI器件、传统模式SOI器件和反偏肖特基势垒SOI DTMOS的关态击穿特性进行了比较.     

SOI反偏肖特基势垒动态阈值MOS特性

将Ti硅化物-p型体区形成的反偏肖特基势垒结构引入绝缘体上硅动态阈值晶体管.传统栅体直接连接DTMOS,为了避免体源二极管的正向开启,工作电压应当低于0.7V.而采用反偏肖特基势垒结构,DTMOS的工作电压可以拓展到0.7V以上.实验结果显示,室温下采用反偏肖特基势垒SOI DTMOS结构,阈值电压可以动态减小200mV.反偏肖特基势垒SOI DTMOS结构相比于传统模式,显示出优秀的亚阈值特性和电流驱动能力.另外,对浮体SOI器件、传统模式SOI器件和反偏肖特基势垒SOI DTMOS的关态击穿特性进行了比较.     

Principles of transient charge pumping on partially depleted SOIMOSFETs

A new method to determine the interface trap density in partially depleted silicon-on-insulator (SOI) floating body MOSFETs is proposed for the first time. It can be considered as a "transient" charge-pumping (CP) technique in contrast to the normally used "steady-state" method. In our technique, majority carriers are removed from the floating body by applying a burst of pulses to the transistor gate. The change in the linear drain current after each pulse is used to determine the device interface trap density. The unique advantage of this method is the possibility to use it to characterize SOI MOSFETs without a body contact. The technique proposed is simple, reliable, and can be used for the characterization of deep submicron devices     

Clarification of floating-body effects on drive current and shortchannel effect in deep sub-0.25 μm partially depleted SOIMOSFETs

We point out for the first time that floating-body effects cause the reduction of the saturation drive current in partially depleted (PD) Sol MOSFETs. It is demonstrated that when the channel concentration of the SOI MOSFETs is set higher in order to suppress the increase of the off current caused by floating-body effects, the drive current decreases due to the large body effect. In the conventional SOI structure where the source-drain junction is in contact with the buried oxide, the 0.18 μm floating PD SOI MOSFET suffers around 17% decrease in the drive current under the same threshold voltage (V_th) in comparison with body-fixed one. However, floating ID SOI MOSFETs show smaller V_th-roll-off. Further considering the short channel effect down to the minimum gate length of 0.16 μm, the current decrease becomes 6%. Also, we propose a floating PD SOI MOSFET with shallow source-drain junction (SSD) structure to suppress the floating-body effects. By using the SSD structure, we confirmed an increase in the drive current     

Comprehensive study on low-frequency noise characteristics insurface channel SOI CMOSFETs and device design optimization for RF ICs

Low-frequency (LF) noise, a key figure-of-merit to evaluate device technology for RF systems on a chip, is a significant obstacle for CMOS technology, especially for partially depleted (PD) silicon-on-insulator (SOI) CMOS due to the well-known kink-induced noise overshoot. While the dc kink effect can be suppressed by either using body contact technologies or shifting toward fully depleted (FD) operation, the noise overshoot phenomena still resides at high frequency for either FD SOI or poor body-tied (BT) SOI CMOSFETs. In this paper, floating body-induced excess noise in SOI CMOS technology is addressed, including the impact from floating body effect, pre-dc kink operation, and gate overdrive, followed by the proposal of a universal LF excess noise model. As the physical mechanism behind excess noise is identified, this paper concludes with the suggestion of a device design methodology to optimize LF noise in SOI CMOSFET technology     

Substrate current measurements in thin SOI MOSFET's at 300 and 77 K

Measurements of impact-ionized hole current in fully depleted SOI (silicon-on-insulator) MOSFETs at room temperature and liquid nitrogen temperature are reported. The measured current exhibits properties similar to those of the substrate current in bulk transistors, except for higher drain biases when the parasitic bipolar in the device is significant. Since the body contact is effective in collecting only a small fraction of the total generated hole current, the body contact cannot be used to eliminate the bipolar action in thin SOI, at least for channel widths on the order of 10 μm     

Status and Trends in Advanced SOI Devices and Materials

A review of recently explored effects in advanced SOI devices and materials is given. The effects of key device parameters on the electrical and thermal floating body effects are shown for various device architectures.Recent advances in the understanding of the sensitivity of electron and hole transport to the tensile or compressive uniaxial and biaxial strains in thin film SOI are presented. The performance and physical mechanisms are also addressed in multi-gate Si, SiGe and Ge MOSFETs. New hot carrier phenomena are discussed. The effects of gate misalignment or underlap,as well as the use of the back gate for charge storage in double-gate nanodevices and of capacitorless DRAM are also outlined.     

Status and Trends in Advanced SOI Devices and Materials

提供了一种用于安德鲁反射测量样品制备新方法. 该方法采用聚焦粒子束刻蚀和磁控溅射,可以获得可控的、干净的、无应力的纳米接触用于自旋极化探测. 所制备的样品中,磁性和非磁性材料样品的反射谱都表现出复杂的峰和谷结构,这些结构可能源于与界面相关的零偏压反常以及与激发态相关的准离子相互作用. 对另一个Co40Fe40B20合金样品采用简单的钕针尖压针方法进行了对比性测量,反射谱中没有观察到谷结构,但谱结构出现较明显的热扩展,这种热扩展可能来源于界面处的非弹性输运. 所有的反射谱目前还不能由现有的理论给出令人满意的解释. 利用点接触反射方法获得可靠的自旋极化信息还有赖于接触界面特征的进一步分析. 而一个更切合实际的、更完善的理论成为迫切的需要.     

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     

A¨nalysis of floating body effects in thin film conventionaland single pocket SOI MOSFETs using the GIDL current technique

Using a novel gate-induced-drain-leakage (GIDL) current technique and two-dimensional (2-D) simulations, single pocket (SP) SOI MOSFETs have been shown to exhibit reduced floating body effects compared to the homogeneously-doped channel (conventional) SOI MOSFETs. The GIDL current technique has been used to characterize the parasitic bipolar transistor gain for both conventional and SP-SOI MOSFETs. From 2-D device simulations, the lower floating body effects in SP-SOI MOSFETs are analyzed and compared with the conventional MOSFETs     

A physical compact DC drain current model for long-channel undoped ultra-thin body (UTB) SOI and asymmetric double-gate (DG) MOSFETs with independent gate operation

In this paper, a new compact charge based DC model for the drain current of long channel fully depleted ultra-thin body SOI MOSFETs and asymmetric double-gate MOSFETs with independent gate operation (ADGMOSFETs) is presented. The model was validated by both TCAD simulations and electrical measurements with a good agreement. In particular, great care was taken during the derivation of the model in order to respect the physics of the device and to make the correct approximations. The obtained solutions can be viewed as a generalization of classical MOS theory to the case of undoped fully depleted ADGMOS. As a result, the model consists of relatively simple equations and is a promising approach for the compact modeling and parameter extraction of fully depleted SOI transistors.     

Asymmetric Schottky Tunneling Source SOI MOSFET Design for Mixed-Mode Applications

Schottky barrier MOSFETs have recently attracted attention as a viable alternative to conventional CMOS transistors for sub-65-nm technology nodes. An asymmetric Schottky tunneling source SOI MOSFET (STS-FET) is proposed in this paper. The Schottky tunneling source SOI MOSFET has the source/drain regions replaced with silicide as opposed to highly doped silicon in conventional devices. The main feature of this device is the concept of a gate-controlled Schottky barrier tunneling at the source. The device was optimized with respect to various parameters such as Schottky barrier height and gate oxide thickness. The optimized device shows excellent short channel immunity, compared to conventional SOI MOSFETs. The asymmetric nature of the device has been shown to improve the leakage current as well as the linear characteristics of the device as compared to conventional Schottky FETs. The STS-FET was fabricated, using conventional processes combined with the present NiSi technology and large angle implantation, and successfully demonstrated. The high immunity to short channel effects improves the scalability, and the output resistance of the device also makes it an attractive candidate for mixed-mode applications.      

Advanced technologies for optimized sub-quarter-micrometer SOI CMOSdevices

Two manufacturable technologies of fully-depleted (FD) thin-film silicon-on-insulator (SOI) MOSFET's for low-power applications are proposed in this paper. To maintain high current drive while aggressively thinning down the SOI film, silicide is to be formed on Ge-damaged silicon layers. Ge preamorphization facilitates silicide formation at low temperature (~450°C) and effectively controls the silicide depth without void formation. It also reduces the floating body effect. In addition, a reliable gate work-function engineering is introduced for good threshold voltage management. A p⁺SiGe/Si stack gate alleviates the threshold voltage instability of SOI due to film thickness nonuniformity and broadens the design window for channel doping. These advanced technologies, compatible with existing bulk CMOS technology, are integrated into SOI CMOS process. Excellent electrical device results are presented