Novel III-V compound semiconductor technologies for low power digital logic applications

As silicon (Si) complementary metal oxide semiconductor (CMOS) technology continues to scale into the 10 nm node, chip power consumption is approaching 200 W/cm2 and any further increase is unsustainable. Incorporating III-V compound semiconductor n-type devices into future CMOS generations could allow for the the reduction in supply voltage, and therefore, power consumption, while simultaneously improving on-state performance. The advanced state of Si CMOS places stringent demands on III-V devices, however: the current 14 nm Si tri-gate devices employ high aspect ratio, densely spaced fins which serve to significantly increase current per chip surface area. III-V devices need to significantly out perform state of the art Si devices in order to merit their disruptive incorporation into the well established CMOS process. This necessitates that they too exploit the vertical dimension. To this end, this thesis reports on the fabrication, measurement and analysis of high aspect ratio junctionless InGaAs FinFETs. The junctionless architecture was first demonstrated in 2010 and was shown to circumvent pro- hibitive fabrication challenges for devices with ultra short gate lengths. This work investigated the impact of fin width on both the on and off-state performance of 200 nm gate length devices, with nominal fin widths of 10, 15 and 20 nm. Excellent subthreshold performance was demonstrated, with the narrowest fin width exhibiting a minimum subthreshold swing (SS) of 73 mV/Dec., and an average SS of 80 mV/Dec. over two decades of current. A maximum on-current, Ion, of 80.51 μA/cm2 was measured at a gate overdrive of 0.5 V from an off-state current, Ioff, of 100 nA/cm2 and a drain voltage, Vd, of 0.5 V, with current normalised by gated perimeter. This is competitive with other III-V junctionless devices at similar gate lengths. With current normalised to base fin width, however, Ion increases to 371.8 μA/cm2, which is a record value among equivalently normalised non-planar III-V junctionless devices at any gate length. This technology, therefore, clearly demonstrates the feasibility of incorporating scaled, etched InGaAs fins into future logic generations. Perhaps the greatest bottleneck to the incorporation of III-V compounds into future CMOS technology nodes, however, is the lack of a suitable III-V PMOS candidate: co-integrating different material systems onto a common substate incurs great fabrication complexity, and therefore, cost. III-V antimonides, however, have recently emerged as promising candidates for III-V PMOS and exhibit the highest bulk electron mobility of all III-Vs in addition to a hole mobility second only to germanium. InGaSb ternary compounds have been shown to offer the best combined performance for electrons and holes in the same material, and as such, have the potential to the enable the most simplistic incarnation of III-V CMOS; provided, of course, that is possible to form a gate stack to both device polarities with sufficient electrical properties. To date, however, there has been no investigation into the high-k dielectric interface to InGaSb. To this end, this thesis presents results of the first investigation into the impact of in-situ H2 plasma exposure on the electrical properties of the p/n-In0.3Ga0.7Sb-Al2O3 interface. The parameter space was explored systematically in terms of H2 plasma power and exposure time, and further, the impact of impact of in-situ trimethylaluminium (TMA) pre-cleaning and annealing in forming gas was assessed. Metal oxide semiconductor capacitors (MOSCAPs) were fabricated subsequent to H2 plasma processing and Al2O3 deposition, and the correspond- ing capacitance-voltage and conductance-voltage measurements were analysed both qualita- tively and quantitatively via the simulation of an equivalent circuit model. X-Ray photoelectron spectroscopy (XPS) analysis of samples processed as part of the plasma power series revealed a combination of ex-situ HCl cleaning and in-situ H2 plasma exposure to completely remove In and Sb sub oxides, with the Ga-O content reduced to Ga-O:InGaSb <0.1. The optimal process, which included ex-situ HCl surface cleaning, in-situ H2 plasma and TMA pre-cleaning, and a post gate metal forming gas anneal, was unequivocally demonstrated to yield a fully unpinnned MOS interface with both n and p-type MOSCAPs explicitly demonstrating a genuine minority carrier response. Interface state and border trap densities were extracted, with a minimum Dit of 1.73x1012 cm-2 eV-1 located at ~110 meV below the conduction band edge and peak border trap densities approximately aligned with the valence and conduction band edges of 3x1019 cm-3 eV-1 and 6.5x1019 cm-3 eV-1 respectively. These results indicate that the optimal gate stack process is indeed applicable to both p and n- type InGaSb MOSFETs, and therefore, represent a critical advancement towards achieving high performance III-V CMOS

Vertical Heterostructure III-V MOSFETs for CMOS, RF and Memory Applications

This thesis focuses mainly on the co-integration of vertical nanowiren-type InAs and p-type GaSb MOSFETs on Si (Paper I & II), whereMOVPE grown vertical InAs-GaSb heterostructure nanowires areused for realizing monolithically integrated and co-processed all-III-V CMOS.Utilizing a bottom-up approach based on MOVPE grown nanowires enablesdesign flexibilities, such as in-situ doping and heterostructure formation,which serves to reduce the amount of mask steps during fabrication. By refiningthe fabrication techniques, using a self-aligned gate-last process, scaled10-20 nm diameters are achieved for balanced drive currents at Ion ∼ 100μA/μm, considering Ioff at 100 nA/μm (VDD = 0.5 V). This is enabledby greatly improved p-type MOSFET performance reaching a maximumtransconductance of 260 μA/μm at VDS = 0.5 V. Lowered power dissipationfor CMOS circuits requires good threshold voltage VT matching of the n- andp-type device, which is also demonstrated for basic inverter circuits. Thevarious effects contributing to VT-shifts are also studied in detail focusing onthe InAs channel devices (with highest transconductance of 2.6 mA/μm), byusing Electron Holography and a novel gate position variation method (PaperV).The advancements in all-III-V CMOS integration spawned individual studiesinto the strengths of the n- and p-type III-V devices, respectively. Traditionallymaterials such as InAs and InGaAs provide excellent electrontransport properties, therefore they are frequently used in devices for highfrequency RF applications. In contrast, the III-V p-type alternatives have beenlacking performance mostly due to the difficult oxidation properties of Sb-based materials. Therefore, a study of the GaSb properties, in a MOSFETchannel, was designed and enabled by new manufacturing techniques, whichallowed gate-length scaling from 40 to 140 nm for p-type Sb-based MOSFETs(Paper III). The new fabrication method allowed for integration of deviceswith symmetrical contacts as compared to previous work which relied on atunnel-contact at the source-side. By modelling based on measured data fieldeffecthole mobility of 70 cm2/Vs was calculated, well in line with previouslyreported studies on GaSb nanowires. The oxidation properties of the GaSbgate-stack was further characterized by XPS, where high intensities of xraysare achieved using a synchrotron source allowed for characterization ofnanowires (Paper VI). Here, in-situ H2-plasma treatment, in parallel with XPSmeasurements, enabled a study of the time-dependence during full removalof GaSb native oxides.The last focus of the thesis was building on the existing strengths of verticalheterostructure III-V n-type (InAs-InGaAs graded channel) devices. Typically,these devices demonstrate high-current densities (gm >3 mS/μm) and excellentmodulation properties (off-state current down to 1 nA/μm). However,minimizing the parasitic capacitances, due to various overlaps originatingfrom a low access-resistance design, has proven difficult. Therefore, newmethods for spacers in both the vertical and planar directions was developedand studied in detail. The new fabrication methods including sidewall spacersachieved gate-drain capacitance CGD levels close to 0.2 fF/μm, which isthe established limit by optimized high-speed devices. The vertical spacertechnology, using SiO2 on the nanowire sidewalls, is further improved inthis thesis which enables new co-integration schemes for memory arrays.Namely, the refined sidewall spacer method is used to realize selective recessetching of the channel and reduced capacitance for large array memoryselector devices (InAs channel) vertically integrated with Resistive RandomAccess Memory (RRAM) memristors. (Paper IV) The fabricated 1-transistor-1-memristor (1T1R) demonstrator cell shows excellent endurance and retentionfor the RRAM by maintaining constant ratio of the high and low resistive state(HRS/LRS) after 106 switching cycles

Function Implementation in a Multi-Gate Junctionless FET Structure

Title from PDF of title page, viewed September 18, 2023Dissertation advisor: Mostafizur RahmanVitaIncludes bibliographical references (pages 95-117)Dissertation (Ph.D.)--Department of Computer Science and Electrical Engineering, Department of Physics and Astronomy. University of Missouri--Kansas City, 2023This dissertation explores designing and implementing a multi-gate junctionless field-effect transistor (JLFET) structure and its potential applications beyond conventional devices. The JLFET is a promising alternative to conventional transistors due to its simplified fabrication process and improved electrical characteristics. However, previous research has focused primarily on the device's performance at the individual transistor level, neglecting its potential for implementing complex functions. This dissertation fills this research gap by investigating the function implementation capabilities of the JLFET structure and proposing novel circuit designs based on this technology. The first part of this dissertation presents a comprehensive review of the existing literature on JLFETs, including their fabrication techniques, operating principles, and performance metrics. It highlights the advantages of JLFETs over traditional metal-oxide-semiconductor field-effect transistors (MOSFETs) and discusses the challenges associated with their implementation. Additionally, the review explores the limitations of conventional transistor technologies, emphasizing the need for exploring alternative device architectures. Building upon the theoretical foundation, the dissertation presents a detailed analysis of the multi-gate JLFET structure and its potential for realizing advanced functions. The study explores the impact of different design parameters, such as channel length, gate oxide thickness, and doping profiles, on the device performance. It investigates the trade-offs between power consumption, speed, and noise immunity, and proposes design guidelines for optimizing the function implementation capabilities of the JLFET. To demonstrate the practical applicability of the JLFET structure, this dissertation introduces several novel circuit designs based on this technology. These designs leverage the unique characteristics of the JLFET, such as its steep subthreshold slope and improved on/off current ratio, to implement complex functions efficiently. The proposed circuits include arithmetic units, memory cells, and digital logic gates. Detailed simulations and analyses are conducted to evaluate their performance, power consumption, and scalability. Furthermore, this dissertation explores the potential of the JLFET structure for emerging technologies, such as neuromorphic computing and bioelectronics. It investigates how the JLFET can be employed to realize energy-efficient and biocompatible devices for applications in artificial intelligence and biomedical engineering. The study investigates the compatibility of the JLFET with various materials and substrates, as well as its integration with other functional components. In conclusion, this dissertation contributes to the field of nanoelectronics by providing a comprehensive investigation into the function implementation capabilities of the multi-gate JLFET structure. It highlights the potential of this device beyond its individual transistor performance and proposes novel circuit designs based on this technology. The findings of this research pave the way for the development of advanced electronic systems that are more energy-efficient, faster, and compatible with emerging applications in diverse fields.Introduction -- Literature review -- Crosstalk principle -- Experiment of crosstalk -- Device architecture -- Simulation & results -- Conclusio

III-V Nanowire MOSFET High-Frequency Technology Platform

This thesis addresses the main challenges in using III-V nanowireMOSFETs for high-frequency applications by building a III-Vvertical nanowire MOSFET technology library. The initial devicelayout is designed, based on the assessment of the current III-V verticalnanowire MOSFET with state-of-the-art performance. The layout providesan option to scale device dimensions for the purpose of designing varioushigh-frequency circuits. The nanowire MOSFET device is described using1D transport theory, and modeled with a compact virtual source model.Device assessment is performed at high frequencies, where sidewall spaceroverlaps have been identified and mitigated in subsequent design iterations.In the final stage of the design, the device is simulated with fT > 500 GHz,and fmax > 700 GHz.Alongside the III-V vertical nanowire device technology platform, adedicated and adopted RF and mm-wave back-end-of-line (BEOL) hasbeen developed. Investigation into the transmission line parameters revealsa line attenuation of 0.5 dB/mm at 50 GHz, corresponding to state-ofthe-art values in many mm-wave integrated circuit technologies. Severalkey passive components have been characterized and modeled. The deviceinterface module - an interconnect via stack, is one of the prominentcomponents. Additionally, the approach is used to integrate ferroelectricMOS capacitors, in a unique setting where their ferroelectric behavior iscaptured at RF and mm-wave frequencies.Finally, circuits have been designed. A proof-of-concept circuit, designedand fabricated with III-V lateral nanowire MOSFETs and mm-wave BEOL, validates the accuracy of the BEOL models, and the circuit design. Thedevice scaling is shown to be reflected into circuit performance, in aunique device characterization through an amplifier noise-matched inputstage. Furthermore, vertical-nanowire-MOSFET-based circuits have beendesigned with passive feedback components that resonate with the devicegate-drain capacitance. The concept enables for device unilateralizationand gain boosting. The designed low-noise amplifiers have matching pointsindependent on the MOSFET gate length, based on capacitance balancebetween the intrinsic and extrinsic capacitance contributions, in a verticalgeometry. The proposed technology platform offers flexibility in device andcircuit design and provides novel III-V vertical nanowire MOSFET devicesand circuits as a viable option to future wireless communication systems

Vertical InAs Nanowire Devices and RF Circuits

Recent decades have seen an exponential increase in the functionality of electronic circuits, allowing for continuous innovation, which benefits society. This increase in functionality has been facilitated by scaling down the dimensions of the most important electronic component in modern electronics: the Si-based MOSFET. By reducing the size of the device, more transistors per chip area is possible. Smaller MOSFETs are also faster and more energy-efficient. In state of the art MOSFETs, the key dimensions are only few nanometers, rapidly approaching a point where the current scaling scheme may not be maintained. Research is ongoing to improve the device performance, mainly focusing on material and structural improvements to the existing MOSFET architecture. In this thesis, MOSFETs based on nanowires, are investigated. Taking advantage of the nanowire geometry, the gate can be wrapped all-around the nanowires for excellent control of the channel. The nanowires are made in a high-mobility III-V semiconductor, InAs, allowing for faster electrons and higher currents than Si. This device type is a potential candidate to either replace or complement Si-based MOSFETs in digital and analogue applications. Single balanced down-conversion mixer circuits were fabricated, consisting of three vertically aligned InAs nanowire MOSFETs and two nanowire resistors. These circuits are shown to operate with voltage gain in the GHz-regime. Individual transistors demonstrated operation with gain at several tens of GHz. A method to characterise the resistivity and metal-semiconductor contact quality has been developed, using the transmission line method adapted for vertical nanowires. This method has successfully been applied to InAs nanowires and shown that low-resistance contacts to these nanowires are possible. To optimise the performance of the device and reach as close to intrinsic operation as possible, parasitic capacitances and resistances in the device structure need to be minimised. A novel self-aligned gate-last fabrication method for vertical InAs nanowire transistors has been developed, that allows for an optimum design of the channel and the contact regions. Transistors fabricated using this method exhibit the best DC performance, in terms of a compromise between the normalised transconductance and sub-threshold swing, of any previously reported vertical nanowire MOSFET

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

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

Simulation of multigate SOI transistors with silicon, germanium and III-V channels

In this work by employing numerical three-dimensional simulations we study the electrical performance and short channel behavior of several multi-gate transistors based on advanced SOI technology. These include FinFETs, triple-gate and gate-all-around nanowire FETs with different channel material, namely Si, Ge, and III-V compound semiconductors, all most promising candidates for future nanoscale CMOS technologies. Also, a new type of transistor called “junctionless nanowire transistor” is presented and extensive simulations are carried out to study its electrical characteristics and compare with the conventional inversion- and accumulation-mode transistors. We study the influence of device properties such as different channel material and orientation, dimensions, and doping concentration as well as quantum effects on the performance of multi-gate SOI transistors. For the modeled n-channel nanowire devices we found that at very small cross sections the nanowires with silicon channel are more immune to short channel effects. Interestingly, the mobility of the channel material is not as significant in determining the device performance in ultrashort channels as other material properties such as the dielectric constant and the effective mass. Better electrostatic control is achieved in materials with smaller dielectric constant and smaller source-to-drain tunneling currents are observed in channels with higher transport effective mass. This explains our results on Si-based devices. In addition to using the commercial TCAD software (Silvaco and Synopsys TCAD), we have developed a three-dimensional Schrödinger-Poisson solver based on the non-equilibrium Green’s functions formalism and in the framework of effective mass approximation. This allows studying the influence of quantum effects on electrical performance of ultra-scaled devices. We have implemented different mode-space methodologies in our 3D quantum-mechanical simulator and moreover introduced a new method to deal with discontinuities in the device structures which is much faster than the coupled-mode-space approach

Intelligent Circuits and Systems

ICICS-2020 is the third conference initiated by the School of Electronics and Electrical Engineering at Lovely Professional University that explored recent innovations of researchers working for the development of smart and green technologies in the fields of Energy, Electronics, Communications, Computers, and Control. ICICS provides innovators to identify new opportunities for the social and economic benefits of society.　 This conference bridges the gap between academics and R&D institutions, social visionaries, and experts from all strata of society to present their ongoing research activities and foster research relations between them. It provides opportunities for the exchange of new ideas, applications, and experiences in the field of smart technologies and finding global partners for future collaboration. The ICICS-2020 was conducted in two broad categories, Intelligent Circuits & Intelligent Systems and Emerging Technologies in Electrical Engineering

Miniaturized Transistors, Volume II

In this book, we aim to address the ever-advancing progress in microelectronic device scaling. Complementary Metal-Oxide-Semiconductor (CMOS) devices continue to endure miniaturization, irrespective of the seeming physical limitations, helped by advancing fabrication techniques. We observe that miniaturization does not always refer to the latest technology node for digital transistors. Rather, by applying novel materials and device geometries, a significant reduction in the size of microelectronic devices for a broad set of applications can be achieved. The achievements made in the scaling of devices for applications beyond digital logic (e.g., high power, optoelectronics, and sensors) are taking the forefront in microelectronic miniaturization. Furthermore, all these achievements are assisted by improvements in the simulation and modeling of the involved materials and device structures. In particular, process and device technology computer-aided design (TCAD) has become indispensable in the design cycle of novel devices and technologies. It is our sincere hope that the results provided in this Special Issue prove useful to scientists and engineers who find themselves at the forefront of this rapidly evolving and broadening field. Now, more than ever, it is essential to look for solutions to find the next disrupting technologies which will allow for transistor miniaturization well beyond silicon’s physical limits and the current state-of-the-art. This requires a broad attack, including studies of novel and innovative designs as well as emerging materials which are becoming more application-specific than ever before