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

ANALYTICAL COMPACT MODELING OF NANOSCALE MULTIPLE-GATE MOSFETS.

L’objectiu principal d’aquest treball és el desenvolupament d’un model compacte per a MOSFETs de múltiple porta d’escala nanomètrica, que sigui analític, basat en la física del dispositiu, i predictiu per a simulacions AC i DC. Els dispositius investigats són el MOSFET estàndar en mode d’inversió, a més d’un nou dispositiu anomenat “junctionless MOSFET” (MOSFET sense unions). El model es va desenvolupar en una formulació compacta amb l’ajuda de l’equació de Poisson i la tècnica de la transformación conforme de Schwarz-Cristoffel. Es varen obtenir les equacions del voltatge llindar i el pendent subllindar. Usant la funció W de Lambert, a més d’una funció de suavització per a la transcició entre les regions de depleció i acumulació, s’obté un model unificat de la densitat de càrrega, vàlid per a tots els modes d’operació del transistor. S’estudien també les dependències entre els paràmetres físics del dispositiu i el seu impacte en el seu rendiment. Es tenen en compteefectes importants de canal curt i de quantització. Es discuteixen també la simetria al voltant de Vds= 0 V, i la continuïtat del corrent de drenador en les derivades d’ordre superior. El model va ser validat mitjançant simulacions TCAD numèriques i mesures experimentals.El objetivo principal de este trabajo es el desarrollo de un modelo compacto para MOSFETs de múltiple puerta de escala nanométrica, que sea analítico, basado en la física del dispositivo, y predictivo para simulaciones AC y DC. Los dispositivos investigados son el MOSFET estándar en modo inversión, además de un nuevo dispositivo llamado “junctionless MOSFET” (MOSFET sin uniones). El modelo se desarrolló en una formulación compacta con la ayuda de la ecuación de Poisson y la técnica de transformación conforme de Schwarz-Cristoffel. Se obtuvieron las ecuaciones del voltaje umbral y la pendiente subumbral. Usando la función W de Lambert, además de una función de suavización para la transición entre las regiones de depleción y acumulación, se obtiene un modelo unificado de la densidad de carga, válido para todos los modos de operación del transistor. Se estudian también las dependencias entre los parámetros físicos del dispositivo y su impacto en su rendimiento. Se tienen en cuenta efectos importantes de canal corto y de cuantización. Se discuten también la simetría alrededor de Vds= 0 V, y la continuidad de la corriente de drenador en las derivadas de orden superior. El modelo fue validado mediante simulaciones TCAD numéricas y medidas experimentales.The main focus is on the development of an analytical, physics-based and predictive DC and AC compact model for nanoscale multiple-gate MOSFETs. The investigated devices are the standard inversion mode MOSFET and a new device concept called junctionless MOSFET. The model is derived in closed-from with the help of Poisson's equation and the conformal mapping technique by Schwarz-Christoffel. Equations for the calculation of the threshold voltage and subthreshold slope are derived. Using Lambert's W-function and a smoothing function for the transition between the depletion and accumulation region, an unified charge density model valid for all operating regimes is developed. Dependencies between the physical device parameters and their impact on the device performance are worked out. Important short-channel and quantization effects are taken into account. Symmetry around Vds = 0 V and continuity of the drain current at derivatives of higher order are discussed. The model is validated versus numerical TCAD simulations and measurement data

Vertical Integration of Germanium Nanowires on Silicon Substrates for Nanoelectronics.

Rapid development of semiconductor industry in recent years has been primarily driven by continuous scaling. As the size of the transistors approaches tens of nanometers, we are faced with challenges due to technological and economic reasons. To this end, unconventional semiconductor materials and novel device structures have attracted a lot of interests as promising candidates to replace the Si-channel MOSFET and help extend Moore’s law. In this dissertation, we focus on chemically-synthesized germanium nanowires, and investigate their potential as electronic devices, especially when vertically integrated on a Si substrate. The contributions of the work are as follows: First, the Vapor-Liquid-Solid method for growing Ge nanowires on (111) Si substrates is explored. In addition to the growth of vertical, taper-free, intrinsic Ge nanowires, strategies for doping the nanowires, forming a radial heterojunction and controlling growth sites are also discussed. Second, the Ge/Si heterojunction obtained via nanowire growth is examined by transmission electron microscopy. We confirm the epitaxial nature of the heterojunction despite the 4% lattice mismatch and determine the transition width to be 10-15 nm. Vertical heterodiodes with independently-tuned doping profile in both Ge and Si are demonstrated. Different devices are obtained, including: (1) a rectifying diode with >1,000,000 on/off ratio and ideality factor of 1.16; (2) a tunnel diode with room temperature negative differential resistance, peak current density of 4.57 kA/cm2 and reversed-bias tunnel current of 3.2 µA/µm; (3) a non-ohmic contact due to large valence band offset between Ge and Si. All observed behaviors are very well supported by theoretical analysis of the devices. In addition, a vertical junctionless transistor with Ge/Si core/shell nanowire channel and surrounding gate is demonstrated. High performance p-type transistor behavior with on state current density of 750 µA/µm and mobility of 282 cm2/V∙s is achieved. Moreover, an analytical model is developed to quantitatively explain the measured data and excellent agreement is obtained. Finally, progress towards the realization of a nanowire tunnel transistor is reported. A physical model for nanowire tunnel transistors is proposed. Preliminary experimental results verified that the device concept works although further optimization is still required to boost its performance.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/120872/1/linchen_1.pd

Caractérisation électrique et modélisation du transport dans matériaux et dispositifs SOI avancés

This thesis is dedicated to the electrical characterization and transport modeling in advanced SOImaterials and devices for ultimate micro-nano-electronics. SOI technology is an efficient solution tothe technical challenges facing further downscaling and integration. Our goal was to developappropriate characterization methods and determine the key parameters. Firstly, the conventionalpseudo-MOSFET characterization was extended to heavily-doped SOI wafers and an adapted modelfor parameters extraction was proposed. We developed a nondestructive electrical method to estimatethe quality of bonding interface in metal-bonded wafers for 3D integration. In ultra-thin fully-depletedSOI MOSFETs, we evidenced the parasitic bipolar effect induced by band-to-band tunneling, andproposed new methods to extract the bipolar gain. We investigated multiple-gate transistors byfocusing on the coupling effect in inversion-mode vertical double-gate SOI FinFETs. An analyticalmodel was proposed and subsequently adapted to the full depletion region of junctionless SOI FinFETs.We also proposed a compact model of carrier profile and adequate parameter extraction techniques forjunctionless nanowires.Cette thèse est consacrée à la caractérisation et la modélisation du transport électronique dans des matériaux et dispositifs SOI avancés pour la microélectronique. Tous les matériaux innovants étudiés(ex: SOI fortement dopé, plaques obtenues par collage etc.) et les dispositifs SOI sont des solutions possibles aux défis technologiques liés à la réduction de taille et à l'intégration. Dans ce contexte,l'extraction des paramètres électriques clés, comme la mobilité, la tension de seuil et les courants de fuite est importante. Tout d'abord, la caractérisation classique pseudo-MOSFET a été étendue aux plaques SOI fortement dopées et un modèle adapté pour l'extraction de paramètres a été proposé. Nous avons également développé une méthode électrique pour estimer la qualité de l'interface de collage pour des plaquettes métalliques. Nous avons montré l'effet bipolaire parasite dans des MOSFET SOI totalement désertés. Il est induit par l’effet tunnel bande-à-bande et peut être entièrement supprimé par une polarisation arrière. Sur cette base, une nouvelle méthode a été développée pour extraire le gain bipolaire. Enfin, nous avons étudié l'effet de couplage dans le FinFET SOI double grille, en mode d’inversion. Un modèle analytique a été proposé et a été ensuite adapté aux FinFETs sans jonction(junctionless). Nous avons mis au point un modèle compact pour le profil des porteurs et des techniques d’extraction de paramètres

Modeling Of Two Dimensional Graphene And Non-graphene Material Based Tunnel Field Effect Transistors For Integrated Circuit Design

The Moore’s law of scaling of metal oxide semiconductor field effect transistor (MOSFET) had been a driving force toward the unprecedented advancement in development of integrated circuit over the last five decades. As the technology scales down to 7 nm node and below following the Moore’s law, conventional MOSFETs are becoming more vulnerable to extremely high off-state leakage current exhibiting a tremendous amount of standby power dissipation. Moreover, the fundamental physical limit of MOSFET of 60 mV/decade subthreshold slope exacerbates the situation further requiring current transport mechanism other than drift and diffusion for the operation of transistors. One way to limit such unrestrained amount of power dissipation is to explore novel materials with superior thermal and electrical properties compared to traditional bulk materials. On the other hand, energy efficient steep subthreshold slope devices are the other possible alternatives to conventional MOSFET based on emerging novel materials. This dissertation addresses the potential of both advanced materials and devices for development of next generation energy efficient integrated circuits. Among the different steep subthreshold slope devices, tunnel field effect transistor (TFET) has been considered as a promising candidate after MOSFET. A superior gate control on source-channel band-to-band tunneling providing subthreshold slopes well below than 60 mV/decade. With the emergence of atomically thin two-dimensional (2D) materials, interest in the design of TFET based on such novel 2D materials has also grown significantly. Graphene being the first and the most studied among 2D materials with exotic electronic and thermal properties. This dissertation primarily considers current transport modeling of graphene based tunnel devices from transport phenomena to energy efficient integrated circuit design. Three current transport models: semi-classical, semi-quantum and numerical simulations are described for the modeling of graphene nanoribbon tunnel field effect transistor (GNR TFET) where the semi-classical model is in close agreement with the quantum transport simulation. Moreover, the models produced are also extended for integrated circuit design using Verilog-A hardware description language for logic design. In order to overcome the challenges associated with the band gap engineering for making graphene transistor for logic operation, the promise of graphene based interlayer tunneling transistors are discussed along with their existing fundamental physical limitation of subthreshold slope. It has been found that such interlayer tunnel transistor has very poor electrostatic gate control on drain current. It gives subthreshold slope greater than the thermionic limit of 60 mV/decade at room temperature. In order to resolve such limitation of interlayer tunneling transistors, a new type of transistor named “junctionless tunnel effect transistor (JTET)” has been invented and modeled for the first time considering graphene-boron nitride (BN)-graphene and molybdenum disulfide (MoS2)-boron nitride (BN) heterostructures, where the interlayer tunneling mechanism controls the source-drain ballistic transport instead of depleting carriers in the channel. Steep subthreshold slope, low power and high frequency THz operation are few of the promising features studied for such graphene and MoS2 JTETs. From current transport modeling to energy efficient integrated circuit design using Verilog-A has been carried out for these new devices as well. Thus, findings in this dissertation would suggest the exciting opportunity of a new class of next generation energy efficient material based transistors as switches

Caractérisation électrique de transistors à effet de champ avancés : transistors sans jonctions, sur réseaux de nanotubes de carbone ou sur nanofil en oxyde d'étain

In this dissertation, the electrical characterization of heavily-doped junctionless transistors (JLTs) and individual tin-oxide (SnO2) nanowire field-effect transistors (FETs) and single-walled carbon nanotube (SWCNT) random network thin film transistors (RN-TFTs) are presented in terms of I-V, C-V, low frequency noise (LFN), and low temperature measurement including a numerical simulation, respectively. As a potential emerging candidate for more than Moore, recently developed heavily doped JLTs were studied in low-temperature (77K ~ 350K) with double gate mode to have physical insights of carrier scattering mechanism with account for both the position of flat-band voltage and doping concentration, respectively. Besides, as a nano-scaled bottom-up device, polymethyl methacrylate passivated individual SnO2 nanowire FET was discussed. A large contribution of channel access resistance to carrier mobility and LFN behavior was found as same as in nano-structure devices. Furthermore, various electrical characteristics of percolation dominant N-type SWCNT RN-TFTs were demonstrated by taking into account for I-V, C-V, LFN and a numerical percolation simulation.Les matériaux de faible dimensionnalité, tels que les nanotubes de carbone, le graphène, les nanofils de semi-conducteurs ou d'oxydes métalliques, présentent des propriétés intéressantes telles qu'un rapport surface/ volume important, des mobilités électroniques élevées, des propriétés thermiques et électriques particulières, avec la possibilité de constituer une alternatives à certaines fonctions CMOS ou d'intégrer de nouvelles fonctions comme la récupération d'énergie ou des capteurs. Pour la bio-détection, les nanofils permettent par exemple d'obtenir une grande sensibilité à la présence de biomolécules cibles grâce à la modification de charge qui accompagne leur hybridation sur des biomolécules sondes greffées à la surface du nanofil et au fort couplage électrostatique de cette charge de surface avec le cœur du nanofil. La fabrication de ce type de structure suit différentes voies: une voie dite "top-down" qui est utilisée par la production microélectronique de masse et qui permet un excellent contrôle technologique grâce à l'utilisation d'équipements, notamment de lithographie, extrêmement performants; une seconde voie moins coûteuse mais moins contrôlée dite "bottom-up" dont un exemple répandu est la réalisation de réseaux aléatoires, obtenus par dispersion de nanostructures réalisées directement sous forme 1D par croissance et en général relativement dopés de façon non nécessairement contrôlée. Dans les deux cas, le mécanisme de base est le contrôle électrostatique du canal par effet de champ d'un ensemble (organisé ou non) de nanostructures. Dans cette thèse, trois types de transistors différents sont explorées ; des transistors à nanofils SnO2, des réseaux aléatoires de nanotubes de carbone, des transistors à nanofil à canal uniformément dopé, dits "junctionless transistors" ou JLTs). Par rapport à la configuration classique d'un transistor MOS à inversion, le contrôle demande en général à être reconsidéré pour tenir compte des spécificités de ce type de structures: topologie du canal, isolants non standards (résines), effets de percolation dans les réseaux désordonné, contrôle électrostatique dans les nanofils fortement dopés, rôle crucial des états d'interface. Le travail s'appuie sur (i) une caractérisation approfondie de ces composants en statique (contrôle du courant), en petit signal (contrôle de la charge) et en bruit (pièges et états d'interfaces), (ii) une analyse critique des méthodologies d'extraction de paramètres et des modèles utilisés pour analyser ce fonctionnement avec dans certains cas l'appui de simulations et (iii) le développement, lorsque cela s'avère nécessaire, de nouvelles méthodologies d'extraction

Electronic Nanodevices

The start of high-volume production of field-effect transistors with a feature size below 100 nm at the end of the 20th century signaled the transition from microelectronics to nanoelectronics. Since then, downscaling in the semiconductor industry has continued until the recent development of sub-10 nm technologies. The new phenomena and issues as well as the technological challenges of the fabrication and manipulation at the nanoscale have spurred an intense theoretical and experimental research activity. New device structures, operating principles, materials, and measurement techniques have emerged, and new approaches to electronic transport and device modeling have become necessary. Examples are the introduction of vertical MOSFETs in addition to the planar ones to enable the multi-gate approach as well as the development of new tunneling, high-electron mobility, and single-electron devices. The search for new materials such as nanowires, nanotubes, and 2D materials for the transistor channel, dielectrics, and interconnects has been part of the process. New electronic devices, often consisting of nanoscale heterojunctions, have been developed for light emission, transmission, and detection in optoelectronic and photonic systems, as well for new chemical, biological, and environmental sensors. This Special Issue focuses on the design, fabrication, modeling, and demonstration of nanodevices for electronic, optoelectronic, and sensing applications

Analytical Modeling of Ultrashort-Channel MOS Transistors

Les geometries de transistors d'avui són al rang de nanòmetres d'un sol dígit. En conseqüència, les funcionalitats dels dispositius es veuen afectades negativament pels efectes de canal curt i de mecànica quàntica (SCE i QMEs). Una transició de la geometria del transistor d'efecte de camp de tipus FinFET a Gate-All-Around (GAA) FETs com FETs de nanofils cilíndrics (NW) i de nanoplaques de silici (SiNS) es preveuen en els propers nodes tecnològics per suprimir els SCE i garantir una major miniaturització del MOSFET Aquesta dissertació se centra en el modelat analític de FETs de tipus NW i SiNS de canal ultracurt.S'introdueix un concepte de dimensions de doble porta (DG) equivalent per transferir un model de potencial de DG analític a FET de NW. Un model de corrent de DG compacte es modifica aprofitant la simetria rotacional dels FET de NW. L'efecte del confinament quàntic (QC) és implementat considerant l'eixamplament addicional de la banda prohibida al càlcul d'una concentració de portadors de càrrega intrínseca efectiva i al càlcul del voltatge llindar. L'efecte de corrent túnel directe de font a drenador (DSDT) a SiNS FET ultraescalats es modela amb el nou mètode de wavelets. Aquest model calcula analíticament la probabilitat de tunelització per a cada energia de l'electró, aproximant la forma de la barrera potencial mitjançant una barrera rectangular amb una altura de barrera equivalent. A causa de la fórmula de corrent túnel de Tsu-Esaki no analíticament integrable, es presenta un mètode analític anomenat model quasi-compacte (QCM). Aquest enfocament requereix, entre altres aproximacions, una iteració de Newton i una interpolació lineal de la densitat de corrent amb efecte túnel. A més, es realitza una anàlisi criogènica de temperatura i dopatge. S'investiga la forta influència de la distància del nivell de Fermi a la font des de la vora de la banda de conducció sobre el pendent subumbral, el corrent i la reducció de la barrera induïda per drenador (DIBL). A més, es demostra i explica la fusió de dos efectes relacionats amb el pendent subumbral i el DIBL. La validesa del concepte de dimensions DG equivalents es demostra mitjançant el mesurament i les dades de simulació de TCAD Sentaurus, mentre que el mètode de wavelets es verifica mitjançant simulacions NanoMOS NEGF.Las geometrías de transistores de hoy están en el rango de nanómetros de un solo dígito. En consecuencia, las funcionalidades de los dispositivos se ven afectadas negativamente por los efectos de canal corto y de mecánica cuántica (SCE y QMEs). Una transición de la geometría del transistor de efecto de campo de tipo FinFET a Gate-All -Around (GAA) FETs tales como FETs de nanohilos cilíndricos (NW) y de nanoplacas de silicio (SiNS) se prevén en los próximos nodos tecnológicos para suprimir los SCE y garantizar una mayor miniaturización del MOSFET. Esta disertación se centra en el modelado analítico de FETs de tipo NW y SiNS de canal ultracorto. Se introduce un concepto de dimensiones de doble puerta (DG) equivalente para transferir un modelo de potencial de DG analítico a FET de NW. Un modelo de corriente de DG compacto se modifica aprovechando la simetría rotacional de los FET de NW. El efecto del confinamiento cuántico (QC) es implementado considerando el ensanchamiento adicional de la banda prohibida en el cálculo de una concentración de portadores de carga intrínseca efectiva y en el cálculo del voltaje de umbral. El efecto de corriente túnel directa de fuente a drenador (DSDT) en SiNS FET ultraescalados se modela con el nuevo método de wavelets. Este modelo calcula analíticamente la probabilidad de tunelización para cada energía del electrón aproximando la forma de la barrera de potencial mediante una barrera rectangular con una altura de barrera equivalente. Usando la fórmula de corriente túnel de Tsu-Esaki no analíticamente integrable, se presenta un método analítico denominado modelo cuasi-compacto (QCM), querequiere una iteración de Newton y una interpolación lineal de la densidad de corriente de efecto túnel. Además, se realiza un análisis criogénico en temperatura y dopaje. Se investiga la fuerte influencia del nivel de Fermi de la fuente la sobre la pendiente subumbral, la corriente y la reducción del efecto DIBL. Además, se demuestra y explica la fusión de dos efectos relacionados con la pendiente subumbral y el DIBL. La validez del concepto de dimensiones DG equivalentes se demuestra mediante datos de mediciones y de simulaciones TCAD Sentaurus, mientras que el método de wavelets se verifica mediante simulaciones NanoMOS NEGF.Today's transistor geometries are in the single-digit nanometer range. Consequently, device functionalities are negatively affected by short-channel and quantum mechanical effects (SCEs & QMEs). A transition from fin field-effect transistor (FinFET) geometry to gate-all-around (GAA) FETs such as cylindrical nanowire (NW) and silicon nanosheet (SiNS) FETs is envisioned in the upcoming technology nodes to suppress SCEs and ensure further MOSFET miniaturization. This dissertation focuses on the analytical modeling of ultrashort-channel NW and SiNS FETs. An equivalent double-gate (DG) dimensions concept is introduced to transfer an analytical DG potential model to NW FETs. A compact DG current model is modified by exploiting the rotational symmetry of NW FETs. The effect of quantum confinement (QC) is implemented by considering the additional bandgap widening in the calculation of an effective intrinsic charge carrier concentration and in the calculation of the threshold voltage. The effect of direct source-to-drain tunneling (DSDT) current in ultrascaled SiNS FETs is modeled with the new wavelet approach. This model calculates the tunneling probability analytically for each electron energy by approximating the potential barrier shape by a rectangular barrier with an equivalent barrier height. Due to the nonanalytically integrable Tsu-Esaki tunneling formula an analytical approach named quasi-compact model (QCM) is presented. This approach requires, among other approximations, a Newton iteration, and a linear interpolation of the tunneling current density. Furthermore, a cryogenic temperature and doping analysis is performed. The strong influence of the distance of the source related Fermi level from the conduction band edge on the subthreshold swing, current, and drain-induced barrier lowering (DIBL) saturation is investigated. Also, the merging of two subthreshold swing and DIBL effects is demonstrated and explained. The validity of the equivalent DG dimensions concept is proven by measurement and TCAD Sentaurus simulation data, while the wavelet approach is verified by NanoMOS NEGF simulations

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