Steep-slope Devices for Power Efficient Adiabatic Logic Circuits

Reducing supply voltage is an effective way to reduce power consumption, however, it greatly reduces CMOS circuits speed. This translates in limitations on how low the supply voltage can be reduced in many applications due to frequency constraints. In particular, in the context of low voltage adiabatic circuits, another well-known technique to save power, it is not possible to obtain satisfactory power-speed trade-offs. Tunnel field-effect transistors (TFETs) have been shown to outperforms CMOS at low supply voltage in static logic implementations, operation due to their steep subthreshold slope (SS), and have potential for combining low voltage and adiabatic. To the best of our knowledge, the adiabatic circuit topologies reported with TFETs do not take into account the problems associated with their inverse current due to their intrinsic p-i-n diode. In this paper, we propose a solution to this problem, demonstrating that the proposed modification allows to significantly improving the performance in terms of power/energy savings compared to the original ones, especially at medium and low frequencies. In addition, we have evaluated the relative advantages of the proposed TFET adiabatic circuits, both at gate and architecture levels, with respect to their static implementations, demonstrating that these are greater than for FinFET transistor designs. Index Terms—Adiabatic logic, TunnelPeer reviewe

Analyse et modélisation des phénomènes de mismatch des transistors MOSFET avancées

For correct operation, certain analog and digital circuits, such as current mirrors or SRAM, require pairs of MOS transistors that are electrically identical. Real devices, however, suffer from random local variations in the electrical parameters, a problem referred to as mismatch. The aim of this thesis is to understand the physical causes of mismatch, to quantify this phenomenon, and to propose solutions that enable to reduce its effects. In this context, four major areas are treated. The first one focuses on the optimization of mismatch measurement methodologies. A new technique for the measurement of Vt and β mismatch and an ID mismatch model are proposed, analyzed and applied to experimental data for 28 nm Bulk and FD SOI technologies. The second area focuses on the characterization of different configurations of MOS transistors in order to propose design architectures that are optimized for certain applications. Specifically, the possibility of replacing LDEMOS with transistors in cascode configuration is analyzed. The third area focuses on the analysis and modeling of mismatch phenomena in advanced Bulk and SOI transistors. Three aspects are analyzed: 1) the impact of the introduction of germanium in P channel of 28nm BULK transistors; 2) the elimination of the metal gate contribution to Vt mismatch by using 20nm Gate-last Bulk technology; 3) a descriptive study of the principal contributions to Vt, β and ID mismatch in 28 and 14 nm FD SOI technologies. The last area treats the mismatch trends with transistor aging. NBTI stress tests were applied to PMOS 28nm FD SOI transistors. Models of the Vt and β mismatch trends as a function of the induced interface traps and fixed charges at the Si/SiO2 interface and in the oxide were developed and discussed.Afin de réaliser correctement leur fonction, certains blocs analogiques ou numériques comme les miroirs de courant ou les SRAM, nécessitent des paires de transistors MOS électriquement identiques. Cependant, les dispositifs sur silicium, même appariés, subissent des variations locales aléatoires ce qui fait varier leurs performances électriques. Ce phénomène est connu sous le nom désappariement. L'objectif de cette thèse est de comprendre les causes physiques de ce désappariement, de le quantifier et de proposer des solutions pour le réduire. Dans ce contexte, quatre thèmes principaux sont développés. Le premier thème se focalise sur l'optimisation des méthodologies de mesures des phénomènes de désappariement. Une nouvelle méthode de mesure du désappariement de Vt et de β ainsi qu'un nouveau modèle de désappariement de ID sont proposés, analysés et appliqués à des données mesurées sur des technologies 28nm Bulk et FD SOI. Le second thème se concentre sur la caractérisation des différentes configurations de transistor MOS afin de proposer l'architecture optimale en fonction des applications visées. Ainsi, la possibilité de remplacer le LDEMOS par une configuration cascode est analysée en détail. Le troisième thème se focalise sur l'analyse et la modélisation des phénomènes de désappariement des transistors MOS avancés. Trois aspects sont analysés : 1) l'introduction du Ge dans le canal P des technologies 28nm BULK, 2) la suppression de la contribution de la grille sur le désappariement de Vt en utilisant la technologie 20 nm métal-Gate-Last 3) un descriptif des principaux contributeurs au désappariement de Vt, β et ID dans les technologies 28 et 14nm FD SOI. Le dernier thème traite du comportement du désappariement des transistors MOS après vieillissement. Un vieillissement NBTI a été appliqué sur des PMOS de la technologie 28nm FD SOI. Des modèles de comportement de Vt et de β en fonction du nombre de charges fixes ou d'états d'interfaces induits à l'interface Si/SiO2 ou dans l'oxyde sont proposés et analysés

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