Ultra-Low Power Ternary CMOS Platform for Physical Synthesis of Multi-Valued Logic and Memory Applications

Department of Electrical EngineeringMotivation of this work is to provide feasible, scalable, and designable multi-valued logic (MVL) device platform for physical synthesis of MVL circuits. Especially, ternary device and its general logic functions are focused, owing to most efficiently reduced circuit complexity per radix (R) increase. By designing the OFF-state constant current, not only the standby power (PS) issue of additional intermediate state is overcome, but also continuous supply voltage (VDD) scaling and dynamic power (PD) scaling are possible owing to single-step I-V characteristics. By applying a novel ternary device concept to CMOS technology with OFF-state current mechanism of band-to-band tunneling (BTBT) currents (IBTBT) and subthreshold diffusion current (Isub), the logic changes from binary to ternary are confirmed using mixed-mode device simulation. I experimentally demonstrate ternary CMOS (T-CMOS) and verified its low-power standard ternary inverter (STI) operation by designing channel profiles in conventional binary CMOS. The realized complementary ternary n/pMOS (T-n/pMOS) have fully gate bias (VG)-independent and symmetrical IBTBT of ~10 pA/???m based on proven ion-implantation process, which produces stable and designable intermediate state (VOM) at exactly VDD/2. To present T-CMOS design frameworks in terms of static noise margin (SNM) enhancement and ultra-low power operation, I develop the compact model of T-CMOS and verify the physical model parameters with experimental data. Through the feasible design of Isub with abrupt channel profile based on low thermal budget process, STI has a SNM of 283 mV (80 % of ideal SNM) at VDD= 1V operation and intermediate state stability of ??VOM < ?? 0.1V, even considering the random-dopant fluctuation (RDF) of 32 nm and 22 nm technology. Continuous VDD scaling below 0.5V (SNM= 40% at VDD = 0.3V) enables STI operation with ultra-low PD and PS based on exponentially reduced IBTBT currents. As MVL and memory (MVM) applications, minimum(MIN)/maximum(MAX) gates, analog-to-digital converter (ADC) circuit, and 5-state latch are studied with T-CMOS compact model. Especially ADC circuits revolutionary decreases number of device and circuit interconnection with 9.6% area of binary system.ope

Development and characterization of high performance transistors on glass

Currently, the electrical drivers behind active-matrix flat-panel displays are polysilicon or amorphous silicon based thin-film transistors (TFTs). The ability to integrate transistors onto the glass substrate offers certain design and performance advantages over package-level integration with bulk silicon ICs; this is commonly referred to as system-on-glass (SOG) or system-on-panel (SOP). System on glass may also lower the manufacturing costs of the entire product. Cell phones, personal digital assistants, and entertainment systems are examples of applications that would benefit from system on glass integration. This project is a joint effort between the Microelectronic Engineering Department at RIT and Corning Incorporated. Thin- film transistors have been fabricated on a new substrate material which consists of a high-quality silicon layer on Corning’s Eagle 2000 flat-panel display glass. The substrate material has the potential of yielding transistors with higher performance than commercialized polysilicon and amorphous silicon thin film transistor technologies. The primary focus of this investigation was to solve the engineering challenges of dopant activation, deposited dielectric quality and interface charge associated with a low-temperature (LT) process. A process that is compatible with the thermal constraints of the glass has been designed and demonstrated through the fabrication of MOS transistor. While the device characteristics demonstrate the on-state and off-state behavior of standard bulk-silicon devices, there are unique features which required an extensive study to understand and explain the governing physics. Device simulation was used to develop a comprehensive model of operation for the devices

Solid State Circuits Technologies

The evolution of solid-state circuit technology has a long history within a relatively short period of time. This technology has lead to the modern information society that connects us and tools, a large market, and many types of products and applications. The solid-state circuit technology continuously evolves via breakthroughs and improvements every year. This book is devoted to review and present novel approaches for some of the main issues involved in this exciting and vigorous technology. The book is composed of 22 chapters, written by authors coming from 30 different institutions located in 12 different countries throughout the Americas, Asia and Europe. Thus, reflecting the wide international contribution to the book. The broad range of subjects presented in the book offers a general overview of the main issues in modern solid-state circuit technology. Furthermore, the book offers an in depth analysis on specific subjects for specialists. We believe the book is of great scientific and educational value for many readers. I am profoundly indebted to the support provided by all of those involved in the work. First and foremost I would like to acknowledge and thank the authors who worked hard and generously agreed to share their results and knowledge. Second I would like to express my gratitude to the Intech team that invited me to edit the book and give me their full support and a fruitful experience while working together to combine this book

Scaling the bulk-driven MOSFET into deca-nanometer bulk CMOS technologies

The International Technology Roadmap for Semiconductors predicts that the nominal power supply voltage, VDD, will fall to 0.7 V by the end of the bulk CMOS era. At that time, it is expected that the long-channel threshold voltage of a MOSFET, VT0, will rise to 35.5% of VDD in order to maintain acceptable off-state leakage characteristics in digital systems. Given the recent push for system-on-a-chip integration, this increasing trend in VT0/VDD poses a serious threat to the future of analog design because it causes traditional analog circuit topologies to experience progressively problematic signal swing limitations in each new process generation. To combat the process-scaling-induced signal swing limitations of analog circuitry, researchers have proposed the use of bulk-driven MOSFETs. By using the bulk terminal as an input rather than the gate, the bulk-driven MOSFET makes it possible to extend the applicability of any analog cell to extremely low power supply voltages because VT0 does not appear in the device\u27s input signal path. Since the viability of the bulk-driven technique was first investigated in a 2 um p-well process, there have been numerous reports of low-voltage analog designs incorporating bulk-driven MOSFETs in the literature - most of which appear in technologies with feature sizes larger than 0.18 um. However, as of yet, no effort has been undertaken to understand how sub-micron process scaling trends have influenced the performance of a bulk-driven MOSFET, let alone make the device more adaptable to the deca-nanometer technologies widely used in the analog realm today. Thus, to further the field\u27s understanding of the bulk-driven MOSFET, this dissertation aims to examine the implications of scaling the device into a standard 90 nm bulk CMOS process. This dissertation also describes how the major disadvantages of a bulk-driven MOSFET - i.e., its reduced intrinsic gain, its limited frequency response and its large layout area requirement - can be mitigated through modifications to the device\u27s vertical doping profile and well structure. To gauge the potency of the proposed process changes, an optimized n-type bulk-driven MOSFET has been designed in a standard 90 nm bulk CMOS process via the 2-D device simulator, ATLAS

Impact of intrinsic parameter fluctuations in ultra-thin body silicon-on-insulator MOSFET on 6-transistor SRAM cell

As CMOS device dimensions are being aggressively scaled, the device characteristic must be assessed against fundamental physical limits. Nanoscale device modelling and statistical circuit analysis is needed to provide designer with ability to explore innovative new MOSFET devices as well as understanding the limits of the scaling process. This work introduces a systematic simulation methodology to investigate the impact of intrinsic parameter fluctuation for a novel Ultra-Thin-Body (UTB) Silicon-on-Insulator (SOI) transistor on the corresponding device and circuits. It provides essential link between physical device-level numerical simulation and circuit-level simulation. A systematic analysis of the effects of random discrete dopants, body thickness variations and line edge roughness on a well scaled 10 nm, 7.5 nm and 5 nm channel length UTB-SOI MOSFET is performed. To fully realise the performance benefits of UTB-SOI based SRAM cells a statistical circuit simulation methodology which can fully capture intrinsic parameter fluctuations information into the compact model is developed. The impact of intrinsic parameter fluctuations on the stability and performance of 6T SRAM has been investigated. A comparison with the behaviour of a 6T SRAM based on a conventional 35 nm MOSFET is also presented

Development of a fully-depleted thin-body FinFET process

The goal of this work is to develop the processes needed for the demonstration of a fully-depleted (FD) thin-body fin field effect transistor (FinFET). Recognized by the 2003 International Technology Roadmap for Semiconductors as an emerging non-classical CMOS technology, FinFETs exhibit high drive current, reduced short-channel effects, an extreme scalability to deep submicron regimes. The approach used in this study will build on previous FinFET research, along with new concepts and technologies. The critical aspects of this research are: (1) thin body creation using spacer etchmasks and oxidation/etchback schemes, (2) use of an oxynitride gate dielectric, (3) silicon crystal orientation effect evaluation, and (4) creation of fully-depleted FinFET devices of submicron gate length on Silicon-on-Insulator (SOI) substrates. The developed process yielded functional FinFETs of both thin body and wide body variety. Electrical tests were employed to describe device behaviour, including their subthreshold characteristics, standard operation, effects of gate misalignment on device performance, and impact of crystal orientation on device drive current. The process is shown to have potential for deep submicron regimes of fin width and gate length, and provides a good foundation for further research of FinFETs and similar technologies at RIT

Tunnel Field Effect Transistors:from Steep-Slope Electronic Switches to Energy Efficient Logic Applications

The aim of this work has been the investigation of homo-junction Tunnel Field Effect Transistors starting from a compact modelling perspective to its possible applications. Firstly a TCAD based simulation study is done to explain the main device characteristics. The main differences of a Tunnel FET with respect to a conventional MOSFET is pointed out and the differences have been explained. A compact DC/AC model has been developed which is capable of describing the I-V characteristics in all regimes of operation. The model takes in to account ambi-polarity, drain side breakdown and all tunneling related physics. A temperature dependence is also added to the model to study the temperature independent behavior of tunneling. The model was further implemented in a Verilog-A based circuit simulator. Following calibration to experimental results of Silicon and strained-Silicon TFETs, the model has been also used to benchmark against a standard CMOS node for digital and analog applications. The circuits built with Tunnel FETs showed interesting temperature behavior which was superior to the compared CMOS node. In the same work, we also explore and propose solutions for using TFETs for low power memory applications. Both volatile and non-volatile memory concepts are investigated and explored. The application of a Tunnel FET as a capacitor-less memory has been experimentally demonstrated for the first time. New device concepts have been proposed and process flows for the same are developed to realize them in the clean room in EPFL

Low-frequency noise in downscaled silicon transistors: Trends, theory and practice

By the continuing downscaling of sub-micron transistors in the range of few to one deca-nanometers, we focus on the increasing relative level of the low-frequency noise in these devices. Large amount of published data and models are reviewed and summarized, in order to capture the state-of-the-art, and to observe that the 1/area scaling of low-frequency noise holds even for carbon nanotube devices, but the noise becomes too large in order to have fully deterministic devices with area less than 10nm×10nm. The low-frequency noise models are discussed from the point of view that the noise can be both intrinsic and coupled to the charge transport in the devices, which provided a coherent picture, and more interestingly, showed that the models converge each to other, despite the many issues that one can find for the physical origin of each model. Several derivations are made to explain crossovers in noise spectra, variable random telegraph amplitudes, duality between energy and distance of charge traps, behaviors and trends for figures of merit by device downscaling, practical constraints for micropower amplifiers and dependence of phase noise on the harmonics in the oscillation signal, uncertainty and techniques of averaging by noise characterization. We have also shown how the unavoidable statistical variations by fabrication is embedded in the devices as a spatial “frozen noise”, which also follows 1/area scaling law and limits the production yield, from one side, and from other side, the “frozen noise” contributes generically to temporal 1/f noise by randomly probing the embedded variations during device operation, owing to the purely statistical accumulation of variance that follows from cause-consequence principle, and irrespectively of the actual physical process. The accumulation of variance is known as statistics of “innovation variance”, which explains the nearly log-normal distributions in the values for low-frequency noise parameters gathered from different devices, bias and other conditions, thus, the origin of geometric averaging in low-frequency noise characterizations. At present, the many models generally coincide each with other, and what makes the difference, are the values, which, however, scatter prominently in nanodevices. Perhaps, one should make some changes in the approach to the low-frequency noise in electronic devices, to emphasize the “statistics behind the numbers”, because the general physical assumptions in each model always fail at some point by the device downscaling, but irrespectively of that, the statistics works, since the low-frequency noise scales consistently with the 1/area law

Study of Soi Annular Mosfet

Annular transistors are enclosed geometry transistors which reduce device leakage by eliminating diffusion edges. Due to the asymmetry of these devices with respect to inner and outer terminals; this study evaluates the behavior of the annular transistor with respect to both the inner and outer drain terminals. Along with this, the effects of geometry of the device on the leakage current and kink effects, related to the NMOS SOS devices at various temperatures are evaluated. Performance of NMOS annular transistor across four different transistor lengths (L= 1.3um, 1.4um 1.5um and 1.6um) are studied along with comparison to a NMOS rectilinear transistors (L=1.4um) at room temperature (RT) and 275C. The experimental results demonstrated a decrease in threshold voltage between the annular transistor with an inner drain compared to the rectilinear transistor by 20% at RT and 33% at 275C. Threshold voltage for an annular transistor with an inner drain is greater than the same transistor with an outer drain by 2% at RT and 3% at 275C. The Ion/Ioff ratio for annular devices with an inner drain compared to a rectangular device shows an improvement of 99% at both RT and 275C. The Ion/Ioff ratio for the same annular transistor with an inner drain verses an outer drain is greater by 75% at RT and 51% at 275C. The kink voltage for an annular transistor with an inner drain is greater than rectangular transistor by 2% at RT while 5% lower at 275C. Kink voltage for annular transistor with an outer drain is greater than the same transistor with an inner drain by 2% at RT and 1% at 275C. Early voltage (VA) for an annular transistor with an inner drain is greater than rectangular transistor by 22% at RT and 21% at 275C. VA for an annular transistor with an inner drain is greater than the same transistor with an outer drain by 22% at RT and 15% at 275C. Output resistance (rds) per unit width of an annular transistor with an inner drain is greater than rectilinear transistor by 77% at RT and 79% at 275C. rds for annular transistor with an inner drain is greater than that with an outer drain of the same device by 4% at RT and is lower by 25% at 275C. In conclusion when it is of the utmost importance to control leakage and device self gain annular transistors provide a significant improvement over the classical rectangular transistor. Some enhanced performance is observed when the inner contact is selected as the drain. It should also be noted that measurement accuracy precludes the taking of any conclusion where changes of less than 2% are observed.School of Electrical & Computer Engineerin