Design, Modeling and Analysis of Non-classical Field Effect Transistors

Transistor scaling following per Moore\u27s Law slows down its pace when entering into nanometer regime where short channel effects (SCEs), including threshold voltage fluctuation, increased leakage current and mobility degradation, become pronounced in the traditional planar silicon MOSFET. In addition, as the demand of diversified functionalities rises, conventional silicon technologies cannot satisfy all non-digital applications requirements because of restrictions that stem from the fundamental material properties. Therefore, novel device materials and structures are desirable to fuel further evolution of semiconductor technologies. In this dissertation, I have proposed innovative device structures and addressed design considerations of those non-classical field effect transistors for digital, analog/RF and power applications with projected benefits. Considering device process difficulties and the dramatic fabrication cost, application-oriented device design and optimization are performed through device physics analysis and TCAD modeling methodology to develop design guidelines utilizing transistor\u27s improved characteristics toward application-specific circuit performance enhancement. Results support proposed device design methodologies that will allow development of novel transistors capable of overcoming limitation of planar nanoscale MOSFETs. In this work, both silicon and III-V compound devices are designed, optimized and characterized for digital and non-digital applications through calibrated 2-D and 3-D TCAD simulation. For digital functionalities, silicon and InGaAs MOSFETs have been investigated. Optimized 3-D silicon-on-insulator (SOI) and body-on-insulator (BOI) FinFETs are simulated to demonstrate their impact on the performance of volatile memory SRAM module with consideration of self-heating effects. Comprehensive simulation results suggest that the current drivability degradation due to increased device temperature is modest for both devices and corresponding digital circuits. However, SOI FinFET is recommended for the design of low voltage operation digital modules because of its faster AC response and better SCEs management than the BOI structure. The FinFET concept is also applied to the non-volatile memory cell at 22 nm technology node for low voltage operation with suppressed SCEs. In addition to the silicon technology, our TCAD estimation based on upper projections show that the InGaAs FinFET, with superior mobility and improved interface conditions, achieve tremendous drive current boost and aggressively suppressed SCEs and thereby a strong contender for low-power high-performance applications over the silicon counterpart. For non-digital functionalities, multi-fin FETs and GaN HEMT have been studied. Mixed-mode simulations along with developed optimization guidelines establish the realistic application potential of underlap design of silicon multi-Fin FETs for analog/RF operation. The device with underlap design shows compromised current drivability but improve analog intrinsic gain and high frequency performance. To investigate the potential of the novel N-polar GaN material, for the first time, I have provided calibrated TCAD modeling of E-mode N-polar GaN single-channel HEMT. In this work, I have also proposed a novel E-mode dual-channel hybrid MIS-HEMT showing greatly enhanced current carrying capability. The impact of GaN layer scaling has been investigated through extensive TCAD simulations and demonstrated techniques for device optimization

Oxygen-insertion Technology for CMOS Performance Enhancement

Until 2003, the semiconductor industry followed Dennard scaling rules to improve complementary metal-oxide-semiconductor (CMOS) transistor performance. However, performance gains with further reductions in transistor gate length are limited by physical effects that do not scale commensurately with device dimensions: short-channel effects (SCE) due to gate-leakage-limited gate-oxide thickness scaling, channel mobility degradation due to enhanced vertical electric fields, increased parasitic resistances due to reductions in source/drain (S/D) contact area, and increased variability in transistor performance due to random dopant fluctuation (RDF) effects and gate work function variations (WFV). These emerging scaling issues, together with increased process complexity and cost, pose severe challenges to maintaining the exponential scaling of transistor dimensions. This dissertation discusses the benefits of oxygen-insertion (OI) technology, a CMOS performance booster, for overcoming these challenges. The benefit of OI technology to mitigate the increase in sheet resistance ($R_{sh}$) with decreasing junction depth ($X_J$) for ultra-shallow-junctions (USJs) relevant for deep-sub-micron planar CMOS transistors is assessed through the fabrication of $R_{sh}$ test structures, electrical characterization, and technology computer-aided design (TCAD) simulations. Experimental and secondary ion mass spectroscopy (SIMS) analyses indicate that OI technology can facilitate low-resistivity USJ formation by reducing $R_{sh}$ and $X_J$ due to retarded transient-enhanced-diffusion (TED) effects and enhanced dopant retention during post-implantation thermal annealing. It is also shown that a low-temperature-oxide (LTO) capping can increase $R_{sh}$ unfavorably due to lower dopant activation levels, which can be alleviated by OI technology. This dissertation extends the evaluation of OI technology to advanced FinFET technology, targeting 7/8-nm low power technology node. A bulk-Si FinFET design comprising a super-steep retrograde (SSR) fin channel doping profile achievable with OI technology is studied by three-dimensional (3-D) TCAD simulations. As compared with the conventional bulk-Si (control) FinFET design with a heavily-doped fin channel doping profile, SSR FinFETs can achieve higher $I_{on}/I_{off}$ ratios and reduce the sensitivity of device performance to variations due to the lightly doped fin channel. As compared with the SOI FinFET design, SSR FinFETs can achieve similarly low $V_{DD,min}$ for 6T-SRAM cell yield estimation. Both SSR and SOI design can provide for as much as 100 mV reduction in $V_{DD,min}$ compared with the control FinFET design. Overall, the SSR FinFET design that can be achieved with OI technology is demonstrated to be a cheaper alternative to the SOI FinFET technology for extending CMOS scaling beyond the 10-nm node. Finally, this dissertation investigates the benefits of OI technology for reducing the Schottky barrier height ($\Phi_{Bp}$) of a Pt/Ti/p-type Si metal-semiconductor (M/S) contact, which can be expected to help reduce the specific contact resistivity for a p-type silicon contact. Electrical measurements of back-to-back Schottky diodes, SIMS, and X-ray photoelectron spectroscopy (XPS) show that the reduction in $\Phi_{Bp}$ is associated with enhanced Ti 2p and Si 2p core energy level shifts. OI technology is shown to favor low-$\Phi_{Bp}$ Pt monosilicide formation during forming gas anneal (FGA) by suppressing the grain boundary diffusion of Pt atoms into the crystalline Si substrate

A statistical study of time dependent reliability degradation of nanoscale MOSFET devices

Charge trapping at the channel interface is a fundamental issue that adversely affects the reliability of metal-oxide semiconductor field effect transistor (MOSFET) devices. This effect represents a new source of statistical variability as these devices enter the nano-scale era. Recently, charge trapping has been identified as the dominant phenomenon leading to both random telegraph noise (RTN) and bias temperature instabilities (BTI). Thus, understanding the interplay between reliability and statistical variability in scaled transistors is essential to the implementation of a ‘reliability-aware’ complementary metal oxide semiconductor (CMOS) circuit design. In order to investigate statistical reliability issues, a methodology based on a simulation flow has been developed in this thesis that allows a comprehensive and multi-scale study of charge-trapping phenomena and their impact on transistor and circuit performance. The proposed methodology is accomplished by using the Gold Standard Simulations (GSS) technology computer-aided design (TCAD)-based design tool chain co-optimization (DTCO) tool chain. The 70 nm bulk IMEC MOSFET and the 22 nm Intel fin-shape field effect transistor (FinFET) have been selected as targeted devices. The simulation flow starts by calibrating the device TCAD simulation decks against experimental measurements. This initial phase allows the identification of the physical structure and the doping distributions in the vertical and lateral directions based on the modulation in the inversion layer’s depth as well as the modulation of short channel effects. The calibration is further refined by taking into account statistical variability to match the statistical distributions of the transistors’ figures of merit obtained by measurements. The TCAD simulation investigation of RTN and BTI phenomena is then carried out in the presence of several sources of statistical variability. The study extends further to circuit simulation level by extracting compact models from the statistical TCAD simulation results. These compact models are collected in libraries, which are then utilised to investigate the impact of the BTI phenomenon, and its interaction with statistical variability, in a six transistor-static random access memory (6T-SRAM) cell. At the circuit level figures of merit, such as the static noise margin (SNM), and their statistical distributions are evaluated. The focus of this thesis is to highlight the importance of accounting for the interaction between statistical variability and statistical reliability in the simulation of advanced CMOS devices and circuits, in order to maintain predictivity and obtain a quantitative agreement with a measured data. The main findings of this thesis can be summarised by the following points: Based on the analysis of the results, the dispersions of VT and ΔVT indicate that a change in device technology must be considered, from the planar MOSFET platform to a new device architecture such as FinFET or SOI. This result is due to the interplay between a single trap charge and statistical variability, which has a significant impact on device operation and intrinsic parameters as transistor dimensions shrink further. The ageing process of transistors can be captured by using the trapped charge density at the interface and observing the VT shift. Moreover, using statistical analysis one can highlight the extreme transistors and their probable effect on the circuit or system operation. The influence of the passgate (PG) transistor in a 6T-SRAM cell gives a different trend of the mean static noise margin

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

Miniaturized Transistors

What is the future of CMOS? Sustaining increased transistor densities along the path of Moore's Law has become increasingly challenging with limited power budgets, interconnect bandwidths, and fabrication capabilities. In the last decade alone, transistors have undergone significant design makeovers; from planar transistors of ten years ago, technological advancements have accelerated to today's FinFETs, which hardly resemble their bulky ancestors. FinFETs could potentially take us to the 5-nm node, but what comes after it? From gate-all-around devices to single electron transistors and two-dimensional semiconductors, a torrent of research is being carried out in order to design the next transistor generation, engineer the optimal materials, improve the fabrication technology, and properly model future devices. We invite insight from investigators and scientists in the field to showcase their work in this Special Issue with research papers, short communications, and review articles that focus on trends in micro- and nanotechnology from fundamental research to applications

Scaling and variability in ultra thin body silicon on insulator (UTB SOI) MOSFETs

The main objective of this thesis is to perform a comprehensive simulation study of the statistical variability in well scaled fully depleted ultra thin body silicon on insulator (FD-UTB SOI) at nanometer regime. It describes the design procedure for template FDUTB SOI transistor scaling and the impacts of statistical variability and reliability the scaled template transistor. The starting point of this study is a systematic simulation analysis based on a welldesigned 32nm thin body SOI template transistor provided by the FP7 project PULLNANO. The 32nm template transistor is consistent with the International Technology Roadmap for Semiconductor (ITRS) 2009 specifications. The wellestablished 3D ‘atomistic’ simulator GARAND has been employed in the designing of the scaled transistors and to carry out the statistical variability simulations. Following the foundation work in characterizing and optimizing the template 32 nm gate length transistor, the scaling proceeds down to 22 nm, 16 nm and 11 nm gate lengths using typically 0.7 scaling factor in respect of the horizontal and vertical transistor dimensions. The device design process is targeted for low power applications with a careful consideration of the impacts of the design parameters choice including buried oxide thickness (TBOX), source/drain doping abruptness (σ) and spacer length (Lspa). In order to determine the values of TBOX, σ, and Lspa, it is important to analyze simulation results, carefully assessing the impact on manufacturability and to consider the corresponding trade-off between short channel effects and on-current performance. Considering the above factors, TBOX = 10nm, σ = 2nm/dec and Lspa = 7nm have been adopted as optimum values respectively. iv The statistical variability of the transistor characteristics due to intrinsic parameter fluctuation (IPF) in well-scaled FD-UTB SOI devices is systematically studied for the first time. The impact of random dopant fluctuation (RDF), line edge roughness (LER) and metal gate granularity (MGG) on threshold voltage (Vth), on-current (Ion) and drain induced barrier lowering (DIBL) are analysed. Each principal sources of variability is treated individually and in combination with other variability sources in the simulation of large ensembles of microscopically different devices. The introduction of highk/ metal gate stack has improved the electrostatic integrity and enhanced the overall device performance. However, in the case of fully depleted channel transistors, MGG has become a dominant variability factor for all critical electrical parameters at gate first technology. For instance, σVth due to MGG increased to 41.9 mV at 11nm gate length compared to 26.0 mV at 22nm gate length. Similar trend has also been observed in σIon, increasing from 0.065 up to 0.174 mA/μm when the gate length is reduced from 22 nm down to 11 nm. Both RDF and LER have significant role in the intrinsic parameter fluctuations and therefore, none of these sources should be overlooked in the simulations. Finally, the impact of different variability sources in combination with positive bias temperature instability (PBTI) degradation on Vth, Ion and DIBL of the scaled nMOSFETs is investigated. Our study indicates that BTI induced charge trapping is a crucial reliability problem for the FD-UTB SOI transistors operation. Its impact not only introduces a significant degradation of transistor performance, but also accelerates the statistical variability. For example, the effect of a late degradation stage (at trap density of 1e12/cm2) in the presence of RDF, LER and MGG results in σVth increase to 36.9 mV, 45.0 mV and 58.3 mV for 22 nm, 16 nm and 11 nm respectively from the original 29.0 mV, 37.9 mV and 50.4 mV values in the fresh transistors

Intrinsic variability of nanoscale CMOS technology for logic and memory.

The continuous downscaling of CMOS technology, the main engine of development of the semiconductor Industry, is limited by factors that become important for nanoscale device size, which undermine proper device operation completely offset gains from scaling. One of the main problems is device variability: nominally identical devices are different at the microscopic level due to fabrication tolerance and the intrinsic granularity of matter. For this reason, structures, devices and materials for the next technology nodes will be chosen for their robustness to process variability, in agreement with the ITRS (International Technology Roadmap for Semiconductors). Examining the dispersion of various physical and geometrical parameters and the effect these have on device performance becomes necessary. In this thesis, I focus on the study of the dispersion of the threshold voltage due to intrinsic variability in nanoscale CMOS technology for logic and for memory. In order to describe this, it is convenient to have an analytical model that allows, with the assistance of a small number of simulations, to calculate the standard deviation of the threshold voltage due to the various contributions

Modelling and simulation study of NMOS Si nanowire transistors

Nanowire transistors (NWTs) represent a potential alternative to Silicon FinFET technology in the 5nm CMOS technology generation and beyond. Their gate length can be scaled beyond the limitations of FinFET gate length scaling to maintain superior off-state leakage current and performance thanks to better electrostatic control through the semiconductor nanowire channels by gate-all-around (GAA) architecture. Furthermore, it is possible to stack nanowires to enhance the drive current per footprint. Based on these considerations, vertically-stacked lateral NWTs have been included in the latest edition of the International Technology Roadmap for Semiconductors (ITRS) to allow for further performance enhancement and gate pitch scaling, which are key criteria of merit for the new CMOS technology generation. However, electrostatic confinement and the transport behaviour in these devices are more complex, especially in or beyond the 5nm CMOS technology generation. At the heart of this thesis is the model-based research of aggressively-scaled NWTs suitable for implementation in or beyond the 5nm CMOS technology generation, including their physical and operational limitations and intrinsic parameter fluctuations. The Ensemble Monte Carlo approach with Poisson-Schrödinger (PS) quantum corrections was adopted for the purpose of predictive performance evaluation of NWTs. The ratio of the major to the minor ellipsoidal cross-section axis (cross-sectional aspect ratio - AR) has been identified as a significant contributing factor in device performance. Until now, semiconductor industry players have carried out experimental research on NWTs with two different cross-sections: circular cylinder (or elliptical) NWTs and nanosheet (or nanoslab) NWTs. Each version has its own benefits and drawbacks; however, the key difference between these two versions is the cross-sectional AR. Several critical design questions, including the optimal NWT cross-sectional aspect ratio, remain unanswered. To answer these questions, the AR of a GAA NWT has been investigated in detail in this research maintaining the cross-sectional area constant. Signatures of isotropic charge distributions within Si NWTs were observed, exhibiting the same attributes as the golden ratio (Phi), the significance of which is well-known in the fields of art and architecture. To address the gap in the existing literature, which largely explores NWT scaling using single-channel simulation, thorough simulations of multiple channels vertically-stacked NWTs have been carried out with different cross-sectional shapes and channel lengths. Contact resistance, non-equilibrium transport and quantum confinement effects have been taken into account during the simulations in order to realistically access performance and scalability. Finally, the individual and combined effects of key statistical variability (SV) sources on threshold voltage (VT), subthreshold slope (SS), ON-current (Ion) and drain-induced barrier lowering (DIBL) have been simulated and discussed. The results indicate that the variability of NWTs is impacted by device architecture and dimensions, with a significant reduction in SV found in NWTs with optimal aspect ratios. Furthermore, a reduction in the variability of the threshold voltage has been observed in vertically-stacked NWTs due to the cancelling-out of variability in double and triple lateral channel NWTs

Caractérisation, mécanismes et applications mémoire des transistors avancés sur SOI

Ce travail présente les principaux résultats obtenus avec une large gamme de dispositifs SOI avancés, candidats très prometteurs pour les futurs générations de transistors MOSFETs. Leurs propriétés électriques ont été analysées par des mesures systématiques, agrémentées par des modèles analytiques et/ou des simulations numériques. Nous avons également proposé une utilisation originale de dispositifs FinFETs fabriqués sur ONO enterré en fonctionnalisant le ONO à des fins d'application mémoire non volatile, volatile et unifiées. Après une introduction sur l'état de l'art des dispositifs avancés en technologie SOI, le deuxième chapitre a été consacré à la caractérisation détaillée des propriétés de dispositifs SOI planaires ultra- mince (épaisseur en dessous de 7 nm) et multi-grille. Nous avons montré l excellent contrôle électrostatique par la grille dans les transistors très courts ainsi que des effets intéressants de transport et de couplage. Une approche similaire a été utilisée pour étudier et comparer des dispositifs FinFETs à double grille et triple grille. Nous avons démontré que la configuration FinFET double grille améliore le couplage avec la grille arrière, phénomène important pour des applications à tension de seuil multiple. Nous avons proposé des modèles originaux expliquant l'effet de couplage 3D et le comportement de la mobilité dans des TFTs nanocristallin ZnO. Nos résultats ont souligné les similitudes et les différences entre les transistors SOI et à base de ZnO. Des mesures à basse température et de nouvelles méthodes d'extraction ont permis d'établir que la mobilité dans le ZnO et la qualité de l'interface ZnO/SiO2 sont remarquables. Cet état de fait ouvre des perspectives intéressantes pour l'utilisation de ce type de matériaux aux applications innovantes de l'électronique flexible. Dans le troisième chapitre, nous nous sommes concentrés sur le comportement de la mobilité dans les dispositifs SOI planaires et FinFET en effectuant des mesures de magnétorésistance à basse température. Nous avons mis en évidence expérimentalement un comportement de mobilité inhabituel (multi-branche) obtenu lorsque deux ou plusieurs canaux coexistent et interagissent. Un autre résultat original concerne l existence et l interprétation de la magnétorésistance géométrique dans les FinFETs.L'utilisation de FinFETs fabriqués sur ONO enterré en tant que mémoire non volatile flash a été proposée dans le quatrième chapitre. Deux mécanismes d'injection de charge ont été étudiés systématiquement. En plus de la démonstration de la pertinence de ce type mémoire en termes de performances (rétention, marge de détection), nous avons mis en évidence un comportement inattendu : l amélioration de la marge de détection pour des dispositifs à canaux courts. Notre concept innovant de FinFlash sur ONO enterré présente plusieurs avantages: (i) opération double-bit et (ii) séparation de la grille de stockage et de l'interface de lecture augmentant la fiabilité et autorisant une miniaturisation plus poussée que des Finflash conventionnels avec grille ONO.Dans le dernier chapitre, nous avons exploré le concept de mémoire unifiée, en combinant les opérations non volatiles et 1T-DRAM par le biais des FinFETs sur ONO enterré. Comme escompté pour les mémoires dites unifiées, le courant transitoire en mode 1T-DRAM dépend des charges non volatiles stockées dans le ONO. D'autre part, nous avons montré que les charges piégées dans le nitrure ne sont pas perturbées par les opérations de programmation et lecture de la 1T-DRAM. Les performances de cette mémoire unifiée multi-bits sont prometteuses et pourront être considérablement améliorées par optimisation technologique de ce dispositif.The evolution of electronic systems and portable devices requires innovation in both circuit design and transistor architecture. During last fifty years, the main issue in MOS transistor has been the gate length scaling down. The reduction of power consumption together with the co-integration of different functions is a more recent avenue. In bulk-Si planar technology, device shrinking seems to arrive at the end due to the multiplication of parasitic effects. The relay has been taken by novel SOI-like device architectures. In this perspective, this manuscript presents the main achievements of our work obtained with a variety of advanced fully depleted SOI MOSFETs, which are very promising candidates for next generation MOSFETs. Their electrical properties have been analyzed by systematic measurements and clarified by analytical models and/or simulations. Ultimately, appropriate applications have been proposed based on their beneficial features.In the first chapter, we briefly addressed the short-channel effects and the diverse technologies to improve device performance. The second chapter was dedicated to the detailed characterization and interesting properties of SOI devices. We have demonstrated excellent gate control and high performance in ultra-thin FD SOI MOSFET. The SCEs are efficiently suppressed by decreasing the body thickness below 7 nm. We have investigated the transport and electrostatic properties as well as the coupling mechanisms. The strong impact of body thickness and temperature range has been outlined. A similar approach was used to investigate and compare vertical double-gate and triple-gate FinFETs. DG FinFETs show enhanced coupling to back-gate bias which is applicable and suitable for dynamic threshold voltage tuning. We have proposed original models explaining the 3D coupling effect in FinFETs and the mobility behavior in ZnO TFTs. Our results pointed on the similarities and differences in SOI and ZnO transistors. According to our low-temperature measurements and new promoted extraction methods, the mobility in ZnO and the quality of ZnO/SiO2 interface are respectable, enabling innovating applications in flexible, transparent and power electronics. In the third chapter, we focused on the mobility behavior in planar SOI and FinFET devices by performing low-temperature magnetoresistance measurements. Unusual mobility curve with multi-branch aspect were obtained when two or more channels coexist and interplay. Another original result in the existence of the geometrical magnetoresistance in triple-gate and even double-gate FinFETs.The operation of a flash memory in FinFETs with ONO buried layer was explored in the forth chapter. Two charge injection mechanisms were proposed and systematically investigated. We have discussed the role of device geometry and temperature. Our novel ONO FinFlash concept has several distinct advantages: double-bit operation, separation of storage medium and reading interface, reliability and scalability. In the final chapter, we explored the avenue of unified memory, by combining nonvolatile and 1T-DRAM operations in a single transistor. The key result is that the transient current, relevant for 1T-DRAM operation, depends on the nonvolatile charges stored in the nitride buried layer. On the other hand, the trapped charges are not disturbed by the 1T-DRAM operation. Our experimental data offers the proof-of-concept for such advanced memory. The performance of the unified/multi-bit memory is already decent but will greatly improve in the coming years by processing dedicated devices.SAVOIE-SCD - Bib.électronique (730659901) / SudocGRENOBLE1/INP-Bib.électronique (384210012) / SudocGRENOBLE2/3-Bib.électronique (384219901) / SudocSudocFranceF

3-D TCAD Monte Carlo device simulator : state-of-the-art FinFET simulation

This work presents a comprehensive description of an in-house 3D Monte Carlo device simulator for physical mod-eling of FinFETs. The simulator was developed to consider var-iability effects properly and to be able to study deeply scaled devices operating in the ballistic and quasi-ballistic regimes. The impact of random dopants and trapped charges in the die-lectric is considered by treating electron-electron and electron-ion interactions in real-space. Metal gate granularity is in-cluded through the gate work functionvariation. The capability to evaluate these effects in nanometer3D devices makes the pre-sented simulator unique, thus advancing the state-of-the-art. The phonon scattering mechanisms, used to model the transport of electrons in puresilicon material system, were validated by comparing simulated drift velocities withavailable experi-mental data. The proper behavior of the device simulator is dis-played in a series of studies of the electric potentialin the device, the electron density, the carrier's energy and velocity, and the Id-Vg and Id-Vd curves