Ultra Low Power SubThreshold Device Design Using New Ion Implantation Profile

Title from PDF of title page, viewed August 14, 2017Dissertation advisor: Masud H. ChowdhuryVitaIncludes bibliographical references (pages 92-97)Thesis (Ph.D.)--School of Computing and Engineering and Department of Physics and Astronomy. University of Missouri--Kansas City, 2016One of the important aspects of integrated circuit design is doping profile of a transistor along its length, width and depth. Devices for super-threshold circuit usually employ halo and retrograde doping profiles in the channel to eliminate many unwanted effects like DIBL, short channel effect, threshold variation etc. These effects are always become a serious issue whenever circuit operates at higher supply voltage. Subthreshold circuit operates at lower supply voltage and these kind of effects will not be a serious issue. Since subthreshold circuit will operate at much lower supply voltage then devices for subthreshold circuit does not require halo and retrograde doping profiles. This will reduce the number of steps in the fabrication process, the parasitic capacitance and the substrate noise dramatically. This dissertation introduces four new doping profiles for devices to be used in the ultra low-power subthreshold circuits. The proposed scheme addresses doping variations along all the dimensions (length, width and depth) of the device. Therefore, the approaches are three dimensional (3D) in nature. This new doping scheme proposes to employ Gaussian distribution of doping concentration along the length of the channel with highest concentration at the middle of the channel. The doping concentration across the depth of the device from the channel region towards the bulk of the device can follow one of the following four distributions: (a) exponentially decreasing, (b) Gaussian, (c) low to high, and (d) uniform doping. The proposed doping scheme keeps the doping concentration along the width of the device uniform. Therefore, under this scheme we achieve four sets of new 3D doping profiles. This dissertation also introduces a new comprehensive doping scheme for the transistors in subthreshold circuits. The proposed doping scheme would bring doping changes in the source and drain areas along with the substrate and channel region of the transistors. The proposed doping scheme is characterized by the absence of halos at the source and drain end. We propose a Gaussian doping distribution inside the source, drain region and a low-high-low distribution across the depth of the transistor from the channel surface towards the body region. It also has a low-high-low doping distribution along the length of the transistor below the channel region. Results show that a device optimized with proposed doping profiles would offer higher ON current in the subthreshold region than a device with the conventional halo and retrograde doping profiles. Among the four 3D doping profiles for subthreshold device some has better ON current than others. Based on specific requirements one of these four doping profiles can be adopted for different ultra-low-power applications. Our analysis shows better subthreshold swing can be achieved using new doping profile based subthreshold design. Results also show that the optimized device with the proposed comprehensive doping profile would provide higher ON current (Iₒₙ) at smaller body bias condition. The analysis is performed by changing the doping profile, body bias and (Vgs) to observe the off-state current (Iₒff), threshold voltage variation, magnitude of Iₒₙ/Iₒff ratio, transconductance and the output conductance with the proposed doping profiles.Introduction -- Subthreshold background -- Implantation profiles -- Threshold voltage calculation -- Comprehensive implantation profile -- Conclusion and future workxvi, 98 page

Multigate MOSFETs for digital performance and high linearity, and their fabrication techniques

The aggressive downscaling of complementary metal–oxide–semiconductor (CMOS) technology is facing great challenges to overcome severe short-channel effects. Multigate MOSFETs are one of the most promising candidates for scaling beyond Si CMOS, due to better electrostatic control as compared to conventional planar MOSFETs. Conventional dry etching-induced surface damage is one of the main sources of performance degradation for multigate transistors, especially for III-V high mobility materials. It is also challenging to increase the fin aspect ratio by dry etching because of the non-ideal anisotropic etching profile. Here, we report a novel method, inverse metal-assisted chemical etching (i-MacEtch), in lieu of conventional RIE etching, for 3D fin channel formation. InP junctionless FinFETs with record high-aspect-ratio (~ 50:1) fins are demonstrated by this method for the first time. The i-MacEtch process flow eliminates dry-etching-induced plasma damage, high energy ion implantation damage, and high temperature annealing, allowing for the fabrication of InP fin channels with atomically smooth sidewalls. The sidewall features resulting from this unique and simplified process ensure high interface quality between high-k dielectric layer and InP fin channel. Experimental and theoretical analyses show that high-aspect-ratio FinFETs, which could deliver more current per area under much relaxed horizontal geometry requirements, are promising in pushing the technology node ahead where conventional scaling has met its physical limits. The performance of the FinFET was further investigated through numerical simulation. A new kind of FinFET with asymmetric gate and source/drain contacts has been proposed and simulated. By benchmarking with conventional symmetric FinFET, better short-channel behavior with much higher current density is confirmed. The design guidelines are provided. The overall circuit delay can be minimized by optimizing gate lengths according to different local parasites among circuits in interconnection-delay-dominated SoC applications. Continued transistor scaling requires even stronger gate electrostatic control over the channel. The ultimate scaling structure would be gate-all-around nanowire MOSFETs. We demonstrate III-V junctionless gate-all-around (GAA) nanowire (NW) MOSFETs for the first time. For the first time, source/drain (S/D) resistance and thermal budget are minimized by regrowth using metalorganic chemical vapor deposition (MOCVD) in III-V MOSFETs. The fabricated short-channel (Lg=80 nm) GaAs GAA NWFETs with extremely narrow nanowire width (WNW= 9 nm) show excellent transconductance (gm) linearity at biases (300 mV), characterized by the high third intercept point (2.6 dBm). The high linearity is especially important for low power applications because it is insensitive to bias conditions

High-Performance Silicon Nanowire Electronics

This thesis explores 10-nm wide Si nanowire (SiNW) field-effect transistors (FETs) for logic applications via the fabrication and testing of SiNW-based ring oscillators. Both SiNW surface treatments and dielectric annealing are reported for producing SiNW FETs that exhibit high performance in terms of large on/off-state current ratio (~108), low drain-induced barrier lowering (~30 mV), high carrier mobilities (~269 cm2/V•s), and low subthreshold swing (~80 mV/dec). The performance of inverter and ring-oscillator circuits fabricated from these nanowire FETs is explored as well. The inverter demonstrates the highest voltage gain (~148) reported for a SiNW-based NOT gate, and the ring oscillator exhibits near rail-to-rail oscillation centered at 13.4 MHz. The static and dynamic characteristics of these NW devices indicate that these SiNW-based FET circuits are excellent candidates for various high-performance nanoelectronic applications. A set of novel charge-trap non-volatile memory devices based on high-performance SiNW FETs are well investigated. These memory devices integrate Fe2O3 quantum dots (FeO QDs) as charge storage elements. A template-assisted assembly technique is used to align FeO QDs into a close-packed, ordered matrix within the trenches that separate highly aligned SiNWs, and thus store injected charges. A Fowler-Nordheim tunneling mechanism describes both the program and erase operations. The memory prototype demonstrates promising characteristics in terms of large threshold voltage shift (~1.3 V) and long data retention time (~3 × 106 s), and also allows for key components to be systematically varied. For example, varying the size of the QDs indicates that larger diameter QDs exhibit a larger memory window, suggesting the QD charging energy plays an important role in the carrier transport. The device temperature characteristics reveal an optimal window for device performance between 275K and 350K. The flexibility of integrating the charge-trap memory devices with the SiNW logic devices offers a low-cost embedded non-volatile memory solution. A building block for a SiNW-based field-programmable gate array (FPGA) is proposed in the future work.</p

Modeling and Simulation of Subthreshold Characteristics of Short-Channel Fully-Depleted Recessed-Source/Drain SOI MOSFETs

Non-conventional metal-oxide-semiconductor (MOS) devices have attracted researchers‟ attention for future ultra-large-scale-integration (ULSI) applications since the channel length of conventional MOS devices approached the physical limit. Among the non-conventional CMOS devices which are currently being pursued for the future ULSI, the fully-depleted (FD) SOI MOSFET is a serious contender as the SOI MOSFETs possess some unique features such as enhanced short-channel effects immunity, low substrate leakage current, and compatibility with the planar CMOS technology. However, due to the ultra-thin source and drain regions, FD SOI MOSFETs possess large series resistance which leads to the poor current drive capability of the device despite having excellent short-channel characteristics. To overcome this large series resistance problem, the source/drain area may be increased by extending S/D either upward or downward. Hence, elevated-source/drain (E-S/D) and recessed-source/drain (Re-S/D) are the two structures which can be used to minimize the series resistance problem. Due to the undesirable issues such as parasitic capacitance, current crowding effects, etc. with E-S/D structure, the Re-S/D structure is a better choice. The FD Re-S/D SOI MOSFET may be an attractive option for sub-45nm regime because of its low parasitic capacitances, reduced series resistance, high drive current, very high switching speed and compatibility with the planar CMOS technology. The present dissertation is to deal with the theoretical modeling and computer-based simulation of the FD SOI MOSFETs in general, and recessed source/drain (Re-S/D) ultra-thin-body (UTB) SOI MOSFETs in particular. The current drive capability of Re-S/D UTB SOI MOSFETs can be further improved by adopting the dual-metal-gate (DMG) structure in place of the conventional single-metal-gate-structure. However, it will be interesting to see how the presence of two metals as gate contact changes the subthreshold characteristics of the device. Hence, the effects of adopting DMG structure on the threshold voltage, subthreshold swing and leakage current of Re-S/D UTB SOI MOSFETs have been studied in this dissertation. Further, high-k dielectric materials are used in ultra-scaled MOS devices in order to cut down the quantum mechanical tunneling of carriers. However, a physically thick gate dielectric causes fringing field induced performance degradation. Therefore, the impact of high-k dielectric materials on subthreshold characteristics of Re-S/D SOI MOSFETs needs to be investigated. In this dissertation, various subthreshold characteristics of the device with high-k gate dielectric and metal gate electrode have been investigated in detail. Moreover, considering the variability problem of threshold voltage in ultra-scaled devices, the presence of a back-gate bias voltage may be useful for ultimate tuning of the threshold voltage and other characteristics. Hence, the impact of back-gate bias on the important subthreshold characteristics such as threshold voltage, subthreshold swing and leakage currents of Re-S/D UTB SOI MOSFETs has been thoroughly analyzed in this dissertation. The validity of the analytical models are verified by comparing model results with the numerical simulation results obtained from ATLAS™, a device simulator from SILVACO Inc

Devenlopment of Compact Small Signal Quasi Static Models for Multiple Gate Mosfets

En esta tesis hemos desarrollado los modelos compactos explícitos de carga y de capacitancia adaptados para los dispositivos dopados y no dopados de canal largo (DG MOSFETs dopados, DG MOSFETs no dopados, UTB MOSFETs no dopados y SGT no dopados) de un modelo unificado del control de carga derivado de la ecuación de Poisson. El esquema de modelado es similar en todos estos dispositivos y se adapta a cada geometría. Los modelos de la C.C. y de la carga son completamente compatibles. Las expresiones de la capacitancia se derivan del modelo de la carga. La corriente, la carga total y las capacitancias se escriben en términos de las densidades móviles de la carga en los extremos de fuente y drenador del canal. Las expresiones explícitas e infinitamente continuas se utilizan para las densidades móviles de la carga en la fuente y drenador. Las capacitancias modeladas demuestran el acuerdo excelente con las simulaciones numéricas 2D y 3D (SGT), en todos los regímenes de funcionamiento. Por lo tanto, el modelo es muy prometedor para ser utilizado en simuladores del circuito. Desafortunadamente, no mucho trabajo se ha dedicado a este dominio de modelado. Las cargas analíticas y las capacitancias, asociadas a cada terminal se prefieren en la simulación de circuito. Con respecto al SGT MOSFET, nuestro grupo fue el primero en desarrollar y publicar un modelo de las cargas y de las capacitancias intrínsecas, que es también analítico y explícito. La tesis es organizada como sigue: el capítulo (1) presenta el estado del arte, capítulo (2) el modelado compacto de los cuatro dispositivos: DG MOSFETs dopados, DG MOSFETs no dopados, UTB MOSFETs no dopados y SGT no dopados; en el capítulo (3) estudiamos las capacitancias de fricción en MuGFETs. Finalmente el capítulo (4) resuma el trabajo hecho y los futuros objetivos que necesitan ser estudiados. Debido a la limitación de los dispositivos optimizados disponibles para el análisis, la simulación numérica fue utilizada como la herramienta principal del análisis. Sin embargo, cuando estaban disponibles, medidas experimentales fueron utilizadas para validar nuestros resultados. Por ejemplo, en la sección 2A, en el caso de DG MOSFETs altamente dopados podríamos comparar nuestros resultados con datos experimentales de FinFETs modelados como DG MOSFETs. La ventaja principal de este trabajo es el carácter analítico y explícito del modelo de la carga y de la capacitancia que las hace fácil de implementar en simuladores de circuitos. El modelo presenta los resultados casi perfectos para diversos casos del dopaje y para diversas estructuras no clásicas del MOSFET (los DG MOSFETs, los UTB MOSFETs y los SGTs). La variedad de las estructuras del MOSFET en las cuales se ha incluido nuestro esquema de modelado y los resultados obtenidos, demuestran su validez absoluta. En el capítulo 3, investigamos la influencia de los parámetros geométricos en el funcionamiento en RF de los MuGFETs. Demostramos el impacto de parámetros geométricos importantes tales como el grosor de la fuente y del drenador o, el espaciamiento de las fins, la anchura del espaciador, etc. en el componente parásito de la capacitancia de fricción de los transistores de la múltiple-puerta (MuGFET). Los resultados destacan la ventaja de disminuir el espaciamiento entre las fins para MuGFETs y la compensación entre la reducción de las resistencias parásitas de fuente y drenador y el aumento de capacitancias de fricción cuando se introduce la tecnología del crecimiento selectivo epitaxial (SEG). La meta de nuestro estudio y trabajo es el uso de nuestros modelos en simuladores de circuitos. El grupo de profesor Aranda, de la Universidad de Granada ha puesto el modelo actual de SGT en ejecución en el simulador Agilent ADS y buenos resultados fueron obtenidos.In this thesis we have developed explicit compact charge and capacitance models adapted for doped and undoped long-channel devices (doped Double-Gate (DG) MOSFETs, undoped DG MOSFETs, undoped Ultra-Thin-Body (UTB) MOSFETs and undoped Surrounding Gate Transistor (SGT)) from a unified charge control model derived from Poisson's equation. The modelling scheme is similar in all these devices and is adapted to each geometry. The dc and charge models are fully compatible. The capacitance expressions are derived from the charge model. The current, total charges and capacitances are written in terms of the mobile charge sheet densities at the source and drain ends of the channel. Explicit and infinitely continuous expressions are used for the mobile charge sheet densities at source and drain. As a result, all small signal parameters will have an infinite order of continuity. The modeled capacitances show excellent agreement with the 2D and 3D (SGT) numerical simulations, in all operating regimes. Therefore, the model is very promising for being used in circuit simulators. Unfortunately, not so much work has been dedicated to this modelling domain. Analytical charges and capacitances, associated with each terminal are preferred in circuit simulation. Regarding the surrounding-gate MOSFET, our group was the first to develop and publish a model of the charges and intrinsic capacitances, which is also analytic and explicit. The thesis is organized as follows: Chapter (1) presents the state of the art, Chapter (2) the compact modeling of the four devices: doped DG MOSFETs, undoped DG MOSFETs, undoped UTB MOSFETs and undoped SGT; in Chapter (3) we study the fringing capacitances in MuGFETs. Finally Chapter (4) summarizes the work done and the future points that need to be studied. Due to the limitation of available optimized devices for analysis, numerical simulation was used as the main analysis tool. However, when available, measurements were used to validate our results. The experimental part was realised at the Microelectronics Laboratory, Université Catholique de Louvain, Louvain-la Neuve, Belgium. For example, in section 2A, in the case of highly-doped DG MOSFETs we could compare our results with experimental data from FinFETs modeled as DG MOSFETs. The main advantage of this work is the analytical and explicit character of the charge and capacitance model that makes it easy to implement in circuit simulators. The model presents almost perfect results for different cases of doping (doped/undoped devices) and for different non classical MOSFET structures (DG MOSFET, UTB MOSFETs and SGT). The variety of the MOSFET structures in which our modeling scheme has been included and the obtained results, demonstrate its absolute validity. In chapter 3, we investigate the influence of geometrical parameters on the RF performance in MuGFETs. We show the impact of important geometrical parameters such as source and drain thickness, fin spacing, spacer width, etc. on the parasitic fringing capacitance component of multiple-gate field-effect transistors (MuGFET). Results highlight the advantage of diminishing the spacing between fins for MuGFETs and the trade-off between the reduction of parasitic source and drain resistances and the increase of fringing capacitances when Selective Epitaxial Growth (SEG) technology is introduced. The goal of our study and work is the usage of our models in circuit simulators. This part, of implementing and testing our models of these multi gate MOSFET devices in circuit simulators has already begun. The group of Professor Aranda, from the University of Granada has implemented the SGT current model in the circuit simulator Agilent ADS and good results were obtained

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 and intrinsic parameter fluctuations in nanoCMOS devices

The core of this thesis is a thorough investigation of the scaling properties of conventional nano-CMOS MOSFETs, their physical and operational limitations and intrinsic parameter fluctuations. To support this investigation a well calibrated 35 nm physical gate length real MOSFET fabricated by Toshiba was used as a reference transistor. Prior to the start of scaling to shorter channel lengths, the simulators were calibrated against the experimentally measured characteristics of the reference device. Comprehensive numerical simulators were then used for designing the next five generations of transistors that correspond to the technology nodes of the latest International Technology Roadmap for Semiconductors (lTRS). The scaling of field effect transistors is one of the most widely studied concepts in semiconductor technology. The emphases of such studies have varied over the years, being dictated by the dominant issues faced by the microelectronics industry. The research presented in this thesis is focused on the present state of the scaling of conventional MOSFETs and its projections during the next 15 years. The electrical properties of conventional MOSFETs; threshold voltage (VT), subthreshold slope (S) and on-off currents (lon, Ioffi ), which are scaled to channel lengths of 35, 25, 18, 13, and 9 nm have been investigated. In addition, the channel doping profile and the corresponding carrier mobility in each generation of transistors have also been studied and compared. The concern of limited solid solubility of dopants in silicon is also addressed along with the problem of high channel doping concentrations in scaled devices. The other important issue associated with the scaling of conventional MOSFETs are the intrinsic parameter fluctuations (IPF) due to discrete random dopants in the inversion layer and the effects of gate Line Edge Roughness (LER). The variations of the three important MOSFET parameters (loff, VT and Ion), induced by random discrete dopants and LER have been comprehensively studied in the thesis. Finally, one of the promising emerging CMOS transistor architectures, the Ultra Thin Body (UTB) SOl MOSFET, which is expected to replace the conventional MOSFET, has been investigated from the scaling point of view