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

Numerical Methods for Parasitic Extraction of Advanced Integrated Circuits

FFinFETs, also known as Fin Field Effect Transistors, are a type of non-planar transistors used in the modern integrated circuits. Fast and accurate parasitic capacitance and resistance extraction is crucial in the design and verification of Fin- FET integrated circuits. Though there are wide varieties of techniques available for parasitic extraction, FinFETs still pose tremendous challenges due to the complex geometries and user model of FinFETs. In this thesis, we propose three practical techniques for parasitic extraction of FinFET integrated circuits. The first technique we propose is to solve the dilemma that foundries and IP vendors face to protect the sensitive information which is prerequisite for accurate parasitic extraction. We propose an innovative solution to the challenge, by building a macro model around any region in 2D/3D on a circuit where foundries or IP vendors wish to hide information, yet the macro model allows accurate capacitance extraction inside and outside of the region. The second technique we present is to reduce the truncation error introduced by the traditional Neumann boundary condition. We make a fundamental contribution to the theory of field solvers by proposing a class of absorbing boundary conditions, which when placed on the boundary of the numerical region, will act as if the region extends to infinity. As a result, we can significantly reduce the size of the numerical region, which in turn reduces the run time without sacrificing accuracy. Finally, we improve the accuracy and efficiency of resistance extraction for Fin-FET with non-orthogonal resistivity interface through FVM and IFEM. The performance of FVM is comparable to FEM but with better stability since the conservation law is guaranteed. The IFEM is even better in both efficiency and mesh generation cost than other methods, including FDM, FEM and FVM. The proposed methods are based on rigorous mathematical derivations and verified through experimental results on practical example

Numerical Methods for Parasitic Extraction of Advanced Integrated Circuits

FFinFETs, also known as Fin Field Effect Transistors, are a type of non-planar transistors used in the modern integrated circuits. Fast and accurate parasitic capacitance and resistance extraction is crucial in the design and verification of Fin- FET integrated circuits. Though there are wide varieties of techniques available for parasitic extraction, FinFETs still pose tremendous challenges due to the complex geometries and user model of FinFETs. In this thesis, we propose three practical techniques for parasitic extraction of FinFET integrated circuits. The first technique we propose is to solve the dilemma that foundries and IP vendors face to protect the sensitive information which is prerequisite for accurate parasitic extraction. We propose an innovative solution to the challenge, by building a macro model around any region in 2D/3D on a circuit where foundries or IP vendors wish to hide information, yet the macro model allows accurate capacitance extraction inside and outside of the region. The second technique we present is to reduce the truncation error introduced by the traditional Neumann boundary condition. We make a fundamental contribution to the theory of field solvers by proposing a class of absorbing boundary conditions, which when placed on the boundary of the numerical region, will act as if the region extends to infinity. As a result, we can significantly reduce the size of the numerical region, which in turn reduces the run time without sacrificing accuracy. Finally, we improve the accuracy and efficiency of resistance extraction for Fin-FET with non-orthogonal resistivity interface through FVM and IFEM. The performance of FVM is comparable to FEM but with better stability since the conservation law is guaranteed. The IFEM is even better in both efficiency and mesh generation cost than other methods, including FDM, FEM and FVM. The proposed methods are based on rigorous mathematical derivations and verified through experimental results on practical example

Simulation of FinFET Structures

The intensive downscaling of MOS transistors has been the major driving force behind the aggressive increases in transistor density and performance, leading to more chip functionality at higher speeds. While on the other side the reduction in MOSFET dimensions leads to the close proximity between source and drain, which in turn reduces the ability of the gate electrode to control the potential distribution and current flow in the channel region and also results in some undesirable effects called the short-channel effects. These limitations associated with downscaling of MOSFET device geometries have lead device designers and researchers to number of innovative techniques which include the use of different device structures, different channel materials, different gate-oxide materials, different processes such as shallow trench isolation, source/drain silicidation, lightly doped extensions etc. to enable controlled device scaling to smaller dimensions. A lot of research and development works have been done in these and related fields and more remains to be carried out in order to exploit these devices for the wider applications

Nano-scale TG-FinFET: Simulation and Analysis

Transistor has been designed and fabricated in the same way since its invention more than four decades ago enabling exponential shrinking in the channel length. However, hitting fundamental limits imposed the need for introducing disruptive technology to take over. FinFET - 3-D transistor - has been emerged as the first successor to MOSFET to continue the technology scaling roadmap. In this thesis, scaling of nano-meter FinFET has been investigated on both the device and circuit levels. The studies, primarily, consider FinFET in its tri-gate (TG) structure. On the device level, first, the main TCAD models used in simulating electron transport are benchmarked against the most accurate results on the semi-classical level using Monte Carlo techniques. Different models and modifications are investigated in a trial to extend one of the conventional models to the nano-scale simulations. Second, a numerical study for scaling TG-FinFET according to the most recent International Technology Roadmap of Semiconductors is carried out by means of quantum corrected 3-D Monte Carlo simulations in the ballistic and quasi-ballistic regimes, to assess its ultimate performance and scaling behavior for the next generations. Ballisticity ratio (BR) is extracted and discussed over different channel lengths. The electron velocity along the channel is analyzed showing the physical significance of the off-equilibrium transport with scaling the channel length. On the circuit level, first, the impact of FinFET scaling on basic circuit blocks is investigated based on the PTM models. 256-bit (6T) SRAM is evaluated for channel lengths of 20nm down to 7nm showing the scaling trends of basic performance metrics. In addition, the impact of VT variations on the delay, power, and stability is reported considering die-to-die variations. Second, we move to another peer-technology which is 28nm FD-SOI as a comparative study, keeping the SRAM cell as the test block, more advanced study is carried out considering the cell‘s stability and the evolution from dynamic to static metrics

Numerical simulation of advanced CMOS and beyond CMOS devices

Co-supervisore: Marco PalaopenLo scaling dei dispositivi elettronici e l'introduzione di nuove opzioni tecnologiche per l'aumento delle prestazioni richiede un costante supporto dal punto di vista della simulazione numerica. Questa tesi si inquadra in tale ambito ed in particolare si prefigge lo scopo di sviluppare due tool software completi basati su tecniche avanzate al fine di predire le prestazioni di dipositivi nano-elettronici progettati per i futuri nodi tecnologiciDottorato di ricerca in Ingegneria industriale e dell'informazioneembargoed_20131103Conzatti, Francesc

Compact modeling of the rf and noise behavior of multiple-gate mosfets

La reducción de la tecnología MOSFET planar ha sido la opción tecnológica dominante en las últimas décadas. Sin embargo, hemos llegado a un punto en el que los materiales y problemas en los dispositivos surgen, abriendo la puerta para estructuras alternativas de los dispositivos. Entre estas estructuras se encuentran los dispositivos DG, SGT y Triple-Gate. Estas tres estructuras están estudiadas en esta tesis, en el contexto de rducir las dimensiones de los dispositivos a tamaños tales que los mecanismos cuánticos y efectos de calan coro deben tenerse n cuenta. Estos efectos vienen con una seria de desafíos desde el pun to de vista de modelación, unos de los más grandes siendo el tiempo y los recursos comprometidos para ejecutar las simulaciones. para resolver este problema, esta tesis propone modelos comlets analíticos y compactos para cada una de las geometrías, validos desde DC hasta el modo de operación en Rf para los nodos tecnológicos futuros. Dichos modelos se han extendido para analizar el ruido de alta frecuencia en estos diapositivos

Device and Circuit Level EMI Induced Vulnerability: Modeling and Experiments

Electro-magnetic interference (EMI) commonly exists in electronic equipment containing semiconductor-based integrated circuits (ICs). Metal-oxide-semiconductor field-effect-transistors (MOSFETs) in the ICs may be disrupted under EMI conditions due to transient voltage-current surges, and their internal states may change undesirably. In this work, the vulnerabilities of silicon MOSFETs under EMI are studied at the device and the circuit levels, categorized as non-permanent upsets (``Soft Errors'') and permanent damages (``Hard Failures''). The Soft Errors, such as temporary bit errors and waveform distortions, may happen or be intensified under EMI, as the transient disruptions activate unwanted and highly non-linear changes inside MOSFETs, such as Impact Ionization and Snapback. The system may be corrected from the erroneous state when the EMI condition is removed. We simulate planar silicon n-type MOSFETs at the device level to study the physical mechanisms leading to or complicate the short-term, signal-level Soft Errors. We experimentally tested commercially available MOSFET devices. Not included in regular MOSFET models, exponential-like current increases as the terminal voltage increases are observed and explained using the device-level knowledge. We develop a compact Soft Error model, compatible with circuit simulators using lumped (or compact-model) components and closed-form expressions, such as SPICE, and calibrate it with our in-house experimental data using an in-house extraction technique based on the Genetic Algorithm. Example circuits are simulated using the extracted device model and under EMI-induced transient disruptions. The EMI voltage-current disruptions may also lead to permanent Hard Failures that cannot be repaired without replacement. One type of Hard Failures, the MOSFET gate dielectric (or ``oxide'') breakdown, can result in input-output relation changes and additional thermal runaway. We have fabricated individual MOSFET devices at the FabLab at the University of Maryland NanoCenter. We experimentally stress-test the fabricated devices and observe the rapid, permanent oxide breakdown. Then, we simulate a nano-scale FinFET device with ultra-thin gate oxide at the device level. Then, we apply the knowledge from our experiments to the simulated FinFET, producing a gate oxide breakdown Hard Failure circuit model. The proposed workflow enables the evaluation of EMI-induced vulnerabilities in circuit simulations before actual fabrication and experiments, which can help the early-stage prototyping process and reduce the development time

Silicon on ferroelectric insulator field effect transistor (SOF-FET) a new device for the next generation ultra low power circuits

Title from PDF of title page, viewed on March 12, 2014Thesis advisor: Masud H. ChowdhuryVitaIncludes bibliographical references (pages 116-131)Thesis (M. S.)--School of Computer and Engineering. University of Missouri--Kansas City, 2013Field effect transistors (FETs) are the foundation for all electronic circuits and processors. These devices have progressed massively to touch its final steps in subnanometer level. Left and right proposals are coming to rescue this progress. Emerging nano-electronic devices (resonant tunneling devices, single-atom transistors, spin devices, Heterojunction Transistors rapid flux quantum devices, carbon nanotubes, and nanowire devices) took a vast share of current scientific research. Non-Si electronic materials like III-V heterostructure, ferroelectric, carbon nanotubes (CNTs), and other nanowire based designs are in developing stage to become the core technology of non-classical CMOS structures. FinFET present the current feasible commercial nanotechnology. The scalability and low power dissipation of this device allowed for an extension of silicon based devices. High short channel effect (SCE) immunity presents its major advantage. Multi-gate structure comes to light to improve the gate electrostatic over the channel. The new structure shows a higher performance that made it the first candidate to substitute the conventional MOSFET. The device also shows a future scalability to continue Moor’s Law. Furthermore, the device is compatible with silicon fabrication process. Moreover, the ultra-low-power (ULP) design required a subthreshold slope lower than the thermionic-emission limit of 60mV/ decade (KT/q). This value was unbreakable by the new structure (SOI-FinFET). On the other hand most of the previews proposals show the ability to go beyond this limit. However, those pre-mentioned schemes have publicized a very complicated physics, design difficulties, and process non-compatibility. The objective of this research is to discuss various emerging nano-devices proposed for ultra-low-power designs and their possibilities to replace the silicon devices as the core technology in the future integrated circuit. This thesis proposes a novel design that exploits the concept of negative capacitance. The new field effect transistor (FET) based on ferroelectric insulator named Silicon-On-Ferroelectric Insulator Field Effect Transistor (SOF-FET). This proposal is a promising methodology for future ultra-lowpower applications, because it demonstrates the ability to replace the silicon-bulk based MOSFET, and offers subthreshold swing significantly lower than 60mV/decade and reduced threshold voltage to form a conducting channel. The SOF-FET can also solve the issue of junction leakage (due to the presence of unipolar junction between the top plate of the negative capacitance and the diffused areas that form the transistor source and drain). In this device the charge hungry ferroelectric film already limits the leakage.Abstract -- List of illustrations - List of tables -- Acknowledgements -- Dedication -- Introduction -- Carbon nanotube field effect transistor -- Multi-gate transistors -FinFET -- Subthreshold swing -- Tunneling field effect transistors -- I-mos and nanowire fets -- Ferroelectric based field effect transistors -- An analytical model to approximate the subthreshold swing for soi-finfet -- Silicon-on-ferroelectric insulator field effect transistor (SOF-FET) -- Current-voltage characteristics of sof-fet -- Advantages, manufacturing process and future work of the proposed device -- Appendix -- Reference