Simulation and Modeling of Novel Electronic Device Architectures with NESS (Nano-Electronic Simulation Software): A Modular Nano TCAD Simulation Framework

The modeling of nano-electronic devices is a cost-effective approach for optimizing the semiconductor device performance and for guiding the fabrication technology. In this paper, we present the capabilities of the new flexible multi-scale nano TCAD simulation software called NanoElectronic Simulation Software (NESS). NESS is designed to study the charge transport in contemporary and novel ultra-scaled semiconductor devices. In order to simulate the charge transport in such ultra-scaled devices with complex architectures and design, we have developed numerous simulation modules based on various simulation approaches. Currently, NESS contains a driftdiffusion, Kubo–Greenwood, and non-equilibrium Green’s function (NEGF) modules. All modules are numerical solvers which are implemented in the C++ programming language, and all of them are linked and solved self-consistently with the Poisson equation. Here, we have deployed some of those modules to showcase the capabilities of NESS to simulate advanced nano-scale semiconductor devices. The devices simulated in this paper are chosen to represent the current state-of-the-art and future technologies where quantum mechanical effects play an important role. Our examples include ultra-scaled nanowire transistors, tunnel transistors, resonant tunneling diodes, and negative capacitance transistors. Our results show that NESS is a robust, fast, and reliable simulation platform which can accurately predict and describe the underlying physics in novel ultra-scaled electronic devices.European Union Horizon 2020 - 688101 SUPERAID7EPSRC UKRI Innovation Fellowship - EP/S001131/1 (QSEE), No. EP/P009972/1 (QUANTDEVMOD)H2020-FETOPEN-2019 s- No.862539-Electromed-FET OPEN.No. EP/S000259/1(Variability PDK for design based research on FPGA/neuro computing

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

높은 전류 구동능력을 가지는 SiGe 나노시트 구조의 터널링 전계효과 트랜지스터

학위논문 (박사) -- 서울대학교 대학원 : 공과대학 전기·정보공학부, 2021. 2. 박병국.The development of very-large-scale integration (VLSI) technology has continuously demanded smaller devices to achieve high integration density for faster computing speed or higher capacity. However, in the recent complementary-metal-oxide-semiconductor (CMOS) technology, simple downsizing the dimension of metal-oxide-semiconductor field-effect transistor (MOSFET) no longer guarantees the boosting performance of IC chips. In particular, static power consumption is not reduced while device size is decreasing because voltage scaling is slowed down at some point. The increased off-current due to short-channel effect (SCE) of MOSFET is a representative cause of the difficulty in voltage scaling. To overcome these fundamental limits of MOSFET, many researchers have been looking for the next generation of FET device over the last ten years. Tunnel field-effect transistor (TFET) has been intensively studied for its steep switching characteristics. Nevertheless, the poor current drivability of TFET is the most serious obstacle to become competitive device for MOSFET. In this thesis, TFET with high current drivability in which above-mentioned problem is significantly solved is proposed. Vertically-stacked SiGe nanosheet channels are used to boost carrier injection and gate control. The fabrication technique to form highly-condensed SiGe nanosheets is introduced. TFET is fabricated with MOSFET with the same structure in the CMOS-compatible process. Both technology-computer-aided-design (TCAD) simulation and experimental results are utilized to support and examine the advantages of proposed TFET. From the perspective of the single device, the improvement in switching characteristics and current drivability are quantitatively and qualitatively analyzed. In addition, the device performance is compared to the benchmark of previously reported TFET and co-fabricated MOSFET. Through those processes, the feasibility of SiGe nanosheet TFET is verified. It is revealed that the proposed SiGe nanosheet TFET has notable steeper switching and low leakage in the low drive voltage as an alternative to conventional MOSFET.초고밀도 집적회로 기술의 발전은 고집적도 달성을 통해 단위 칩의 연산 속도 및 용량 향상에 기여할 소형의 소자를 끊임없이 요구하고 있다. 하지만 최신의 상보형 금속-산화막-반도체 (CMOS) 기술에서 금속-산화막-반도체 전계 효과 트랜지스터 (MOSFET) 의 단순한 소형화는 더 이상 집적회로의 성능 향상을 보장해 주지 못하고 있다. 특히 소자의 크기가 줄어드는 반면 정적 전력 소모량은 전압 스케일링의 둔화로 인해 감소되지 않고 있는 상황이다. MOSFET의 짧은 채널 효과로 인해 증가된 누설 전류가 전압 스케일링의 어려움을 주는 대표적 원인으로 꼽힌다. 이러한 근본적인 MOSFET의 한계를 극복하기 위하여 지난 10여년간 새로운 단계의 전계 효과 트랜지스터 소자들이 연구되고 있다. 그 중 터널 전계 효과 트랜지스터(TFET)은 그 특유의 우수한 전원 특성으로 각광받아 집중적으로 연구되고 있다. 많은 연구에도 불구하고, TFET의 부족한 전류 구동 능력은 MOSFET의 대체재로 자리매김하는 데 가장 큰 문제점이 되고 있다. 본 학위논문에서는 상기된 문제점을 해결할 수 있는 우수한 전류 구동 능력을 가진 TFET이 제안되었다. 반송자 유입과 게이트 컨트롤을 향상시킬 수 있는 수직 적층된 실리콘저마늄(SiGe) 나노시트 채널이 사용되었다. 또한, 제안된 TFET은 CMOS 기반 공정을 활용하여 MOSFET과 함께 제작되었다. 테크놀로지 컴퓨터 지원 설계(TCAD) 시뮬레이션과 실제 측정 결과를 활용하여 제안된 소자의 우수성을 검증하였다. 단위 CMOS 소자의 관점에서, 전원 특성과 전류 구동 능력의 향상을 정량적, 정성적 방법으로 분석하였다. 그리고, 제작된 소자의 성능을 기존 제작 및 보고된 TFET 및 함께 제작된 MOSSFET과 비교하였다. 이러한 과정을 통해, 실리콘저마늄 나노시트 TFET의 활용 가능성이 입증되었다. 제안된 실리콘저마늄 나노시트 소자는 주목할 만한 전원 특성을 가졌고 저전압 구동 환경에서 한층 더 낮은 누설 전류를 가짐으로써 향후 MOSFET을 대체할만한 충분한 가능성을 보여주었다.Chapter 1 Introduction 1 1.1. Power Crisis of Conventional CMOS Technology 1 1.2. Tunnel Field-Effect Transistor (TFET) 6 1.3. Feasibility and Challenges of TFET 9 1.4. Scope of Thesis 11 Chapter 2 Device Characterization 13 2.1. SiGe Nanosheet TFET 13 2.2. Device Concept 15 2.3. Calibration Procedure for TCAD simulation 17 2.4. Device Verification with TCAD simulation 21 Chapter 3 Device Fabrication 31 3.1. Fabrication Process Flow 31 3.2. Key Processes for SiGe Nanosheet TFET 33 3.2.1. Key Process 1 : SiGe Nanosheet Formation 34 3.2.2. Key Process 2 : Source/Drain Implantation 41 3.2.3. Key Process 3 : High-κ/Metal gate Formation 43 Chapter 4 Results and Discussion 53 4.1. Measurement Results 53 4.2. Analysis of Device Characteristics 56 4.2.1. Improved Factors to Performance in SiGe Nanosheet TFET 56 4.2.2. Performance Comparison with SiGe Nanosheet MOSFET 62 4.3. Performance Evaluation through Benchmarks 64 4.4. Optimization Plan for SiGe nanosheet TFET 66 4.4.1. Improvement of Quality of Gate Dielectric 66 4.4.2. Optimization of Doping Junction at Source 67 Chapter 5 Conclusion 71 Bibliography 73 Abstract in Korean 81 List of Publications 83Docto

Investigation on Performance Metrics of Nanoscale Multigate MOSFETs towards RF and IC Applications

Silicon-on-Insulator (SOI) MOSFETs have been the primary precursor for the CMOS technology since last few decades offering superior device performance in terms of package density, speed, and reduced second order harmonics. Recent trends of investigation have stimulated the interest in Fully Depleted (FD) SOI MOSFET because of their remarkable scalability efficiency. However, some serious issues like short channel effects (SCEs) viz drain induced barrier lowering (DIBL), Vth roll-off, subthreshold slope (SS), and hot carrier effects (HCEs) are observed in nanoscale regime. Numerous advanced structures with various engineering concepts have been addressed to reduce the above mentioned SCEs in SOI platform. Among them strain engineering, high-k gate dielectric with metal gate technology (HKMG), and non-classical multigate technologies are most popular models for enhancement in carrier mobility, suppression of gate leakage current, and better immunization to SCEs. In this thesis, the performance of various emerging device designs are analyzed in nanoscale with 2-D modeling as well as through calibrated TCAD simulation. These attempts are made to reduce certain limitations of nanoscale design and to provide a significant contribution in terms of improved performances of the miniaturized devices. Various MOS parameters like gate work function (_m), channel length (L), channel thickness (tSi), and gate oxide thickness (tox) are optimized for both FD-SOI and Multiple gate technology. As the semiconductor industries migrate towards multigate technology for system-on-chip (SoC), system-in-package (SiP), and internet-of-things (IoT) applications, an appropriate examination of the advanced multiple gate MOFETs is required for the analog/RF application keeping reliability issue in mind. Various non-classical device structures like gate stack engineering and halo doping in the channel are extensively studied for analog/RF applications in double gate (DG) platform. A unique attempt has been made for detailed analysis of the state-of-the-art 3-D FinFET on dependency of process variability. The 3-D architecture is branched as Planar or Trigate or FinFET according to the aspect ratio (WFin=HFin). The evaluation of zero temperature coefficient (ZTC) or temperature inflection point (TCP) is one of the key investigation of the thesis for optimal device operation and reliability. The sensitivity of DG-MOSFET and FinFET performances have been addressed towards a wide range of temperature variations, and the ZTC points are identified for both the architectures. From the presented outcomes of this work, some ideas have also been left for the researchers for design of optimum and reliable device architectures to meet the requirements of high performance (HP) and/or low standby power (LSTP) applications

Monolayer doping of bulk and thin body group IV semiconductors

The turn of the new year from 2019-2020 has brought us into a new decade with an unforeseen worldwide halt to what was previously considered “normal” life, due to a virus (coronavirus-19) with dimensions measured by scanning electron microscopy (SEM) to be in the nanometre range. This has emphasized the importance for the general public of acknowledging particles and materials in this nanometre range which cannot be seen without electron microscopy. Some of the technology being used to fight these viruses, such as ventilators, operate using electronics which contain semiconductor materials. Since the mid 1900 s the size of these electronics has decreased while doubling their quantity of transistors in line with Moore’s law. This has allowed for increased performance with lower power consumption. Scaling of metal-oxide-semiconductor field effect transistors (MOSFETs) has progressed from the original micrometre range to current sub-10 nm dimensions, while also moving from planar to 3-dimensional (3-D) architectures. However, increasing difficulty has been found with these new and reduced material dimensions. All fabrication processes are stressed, but doping has particularly found limitations in this region. High concentrations of dopant atoms are required at increasingly shallow depths, while maintaining the crystalline integrity of the planar or 3-D doped substrate. Traditional methods of introducing these dopant atoms, such as ion implantation, have found difficulty with damage production and conformality on state-of-the-art applications. Monolayer doping, which is a method of semiconductor doping through chemical functionalisation of the target substrate with the required dopant-containing molecules, has shown promise as an alternative method for this state-of-the-art doping.The aim of this thesis is to study the potential of monolayer doping for application to materials used in current and future transistor devices

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

Device Design Parameterization of III-V Multi-Gate FETs

The use of group III-V semiconductor materials promise superior performance compared to silicon and can be considered a fundamental paradigm shift away from mature silicon technology. Group III-V semiconductors allow for high power operation, drastically high clock speeds, large breakdown fields, and higher Johnson’s Figure of Merit (JFoM). Due to higher electron drift velocity (vd) of the material set, higher on-state current (Ion) is expected than the one in silicon with reduced supply voltage operation. Additionally, strong spontaneous and piezoelectric polarization properties in the III-Nitrides support tighter carrier confinement with high carrier density in a quantum well channel at the heterointerface. By engineering the III-nitride properties, designing a 3D architecture device includes important physical parameters that must be taken into account to analyze device performance. GaN-based devices are desirable for high RF and high power applications for reducing parasitics and improving efficiency. For this reason, III-nitride semiconductor materials provide the possibility of future integration of GaN fin-based 3D devices. This dissertation describes the experimental realization and electrical analysis of III-V FinFET devices with an AlGaN/GaN heterostructure, called “Multi-Gate Heterostructure Fin Field Effect Transistor (MUG-HFinFET).” Process development begins with the experimental demonstration of a Si-compatible baseline AlGaN/GaN FinFET technology, and an exploration of the impact of physical device design parameters such as fin widths, heights, angles and gate lengths. The ohmic contact formation on AlGaN/GaN heterostructure is realized using different metal stacks while taking into account additional annealing effects and produces comparably low contact resistance to other literature reports. Different fabrication processes to distinguish the impact of the device architectures are demonstrated while simultaneously applying for the integration of high-k dielectric metal-gate stack including surface clean and passivation techniques developed for high quality interfaces and low-leakage performance. After MUG-HFinFET technology is implemented and characterized, the impacts of the device design parameters are benchmarked and shows the guidance to device design at the initial stage forward proper device application. The work concludes by assessing the novel characteristics of AlGaN/GaN heterostructure FinFET devices for 3D device design with distinguished performance. According to the distinguished performance across the device geometries and crystal directions, the benchmarks made in this dissertation will guide future device application development toward an AlGaN/GaN FinFET device design to ensure that a proper device design is achieved