Monte Carlo simulations of high-performance implant free In_0.3Ga_0.7 nano-MOSFETs for low-power CMOS applications

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Ultra-thin plasma nitrided oxide gate dielectrics for advanced MOS transistors

Ultra-thin plasma nitrided oxides have been optimized with the objective to decrease JG and maximize carrier mobility. It was found that while the base oxide cannot be aggressively scaled, plasma optimization yields better mobility thereby increase transistor performance. A summary of the EOT versus gate leakage current density of NMOS devices with plasma nitrided oxides is shown in Figure 5.19. EOT down to 1.2 nm has been achieved with a gate leakage current density of 40 A/cm2 at 1 V operating voltage

Numerical simulation of sub-100 nm strained Si/SiGe MOSFETs for RF and CMOS applications

Drift-Diffusion, Hydrodynamic and Monte Carlo simulations have been used in this work to simulate strained Si/SiGe devices for RF and CMOS applications. For numerical simulations of Si/SiGe devices, strain effects on the band structure of Si have been analyzed and analytical expressions are presented for parameters related to the bandgap and band alignment of Si/SiGe heterostructure. Optimization of n-type buried strained Si channel Si/SiGe MODFETs has been carried out in order to achieve high RF performance and high linearity. The impact of both lateral and vertical device geometries and different doping strategies has been investigated. The impact of the Ge content of the SiGe buffer on the performance of p-type surface channel strained Si/SiGe MOSFETs has been studied. Hydrodynamic device simulations have been used to assess the device performance of p-type strained Si/SiGe MOSFETs down to 35 nm gate lengths. Well-tempered strained Si MOSFETs with halo implants around the source/drain regions have been simulated and compared with those devices possessing only a single retrograde channel doping. The calibrations in respect of sub-100 nm Si and strained Si MOSFETs fabricated by IBM lead to a scaling study of those devices at 65 nm, 45 nm and 35 nm gate lengths. Using Drift-Diffusion simulations, ring oscillator circuit behaviour has been evaluated. Strained Si on insulator (SSOI) circuits have also been simulated and compared with strained Si circuits, Si circuits employing conventional surface channel MOSFETs along with SOI devices. Ensemble Monte Carlo simulations have been used to evaluate the device performance of n-type strained Si MOSFETs. A non-perturbative interface roughness scattering model has been used and validated by calibrating with respect to experimental mobility behaviour and device characteristics. The impact of interface roughness on the performance enhancement of strained Si MOSFETs has been investigated and evidence for reduced interface roughness scattering is presented, i.e., a smoother interface is suggested in strained Si MOSFETs. A 35 nm gate length Toshiba Si MOSFET has been simulated and the performance enhancement of 35 nm strained Si MOSFETs over the Toshiba Si device is predicted. Monte Carlo simulations are also employed to investigate the performance degradation due to soft-optical phonon scattering, which arises with the introduction of high-K gate dielectrics. Based on the device structures of the calibrated sub-100 nm n-type conventional and strained Si IBM MOSFETs, significant current degradation has been observed in devices with high-K gate dielectrics, HfO2 and Al2O3

Negative Bias Temperature Instability And Charge Trapping Effects On Analog And Digital Circuit Reliability

Nanoscale p-channel transistors under negative gate bias at an elevated temperature show threshold voltage degradation after a short period of stress time. In addition, nanoscale (45 nm) n-channel transistors using high-k (HfO2) dielectrics to reduce gate leakage power for advanced microprocessors exhibit fast transient charge trapping effect leading to threshold voltage instability and mobility reduction. A simulation methodology to quantify the circuit level degradation subjected to negative bias temperature instability (NBTI) and fast transient charge trapping effect has been developed in this thesis work. Different current mirror and two-stage operation amplifier structures are studied to evaluate the impact of NBTI on CMOS analog circuit performances for nanoscale applications. Fundamental digital circuit such as an eleven-stage ring oscillator has also been evaluated to examine the fast transient charge transient effect of HfO2 high-k transistors on the propagation delay of ring oscillator performance. The preliminary results show that the negative bias temperature instability reduces the bandwidth of CMOS operating amplifiers, but increases the amplifier\u27s voltage gain at mid-frequency range. The transient charge trapping effect increases the propagation delay of ring oscillator. The evaluation methodology developed in this thesis could be extended to study other CMOS device and circuit reliability issues subjected to electrical and temperature stresses

Negative Bias Temperature Instability And Charge Trapping Effects On Analog And Digital Circuit Reliability

Nanoscale p-channel transistors under negative gate bias at an elevated temperature show threshold voltage degradation after a short period of stress time. In addition, nanoscale (45 nm) n-channel transistors using high-k (HfO2) dielectrics to reduce gate leakage power for advanced microprocessors exhibit fast transient charge trapping effect leading to threshold voltage instability and mobility reduction. A simulation methodology to quantify the circuit level degradation subjected to negative bias temperature instability (NBTI) and fast transient charge trapping effect has been developed in this thesis work. Different current mirror and two-stage operation amplifier structures are studied to evaluate the impact of NBTI on CMOS analog circuit performances for nanoscale applications. Fundamental digital circuit such as an eleven-stage ring oscillator has also been evaluated to examine the fast transient charge transient effect of HfO2 high-k transistors on the propagation delay of ring oscillator performance. The preliminary results show that the negative bias temperature instability reduces the bandwidth of CMOS operating amplifiers, but increases the amplifier\u27s voltage gain at mid-frequency range. The transient charge trapping effect increases the propagation delay of ring oscillator. The evaluation methodology developed in this thesis could be extended to study other CMOS device and circuit reliability issues subjected to electrical and temperature stresses

Growth Stress Induced Tunability of Dielectric Constant in Thin Films

It is demonstrated here that growth stress has a substantial effect on the dielectric constant of zirconia thin films. The correct combination of parameters - phase, texture and stress - is shown to yield films with high dielectric constant and best reported equivalent oxide thickness of 0.8 nm. The stress effect on dielectric constant is twofold, firstly, by the effect on phase transitions and secondly by the effect on interatomic distances. We discuss and explain the physical mechanisms involved in the interplay between the stress, phase changes and the dielectric constant in detail.Comment: 11 pages, 5 figure

Fin Field Effect Transistors Performance in Analog and RF for High-k Dielectrics

The high-k is needed to replace SiO2 as the gate dielectric to reduce the gate leakage current. The impact of a high-k gate dielectric on the device short channel performance and scalability of nanoscale double gate Fin Field Effect Transistors (FinFET) CMOS is examined by 2-D device simulations. DG FinFETs are designed with high-k at the high performance node of the 2008 Semiconductor Industry Association International Technology Roadmap for Semiconductors (ITRS). DG FinFET CMOS can be optimally designed to yield outstanding performance with good trade-offs between speed and power consumption as the gate length is scaled to < 10 nm. Using technology computer aided design (TCAD) tools a 2-D FinFET device is created and the simulations are performed on it. The optimum value of threshold voltage is identified as VT=0.653V with e=23(ZrO2) for the 2-D device structure. For the 2-D device structure, the leakage current has been reduced to 9.47´10-14 A. High-k improves the Ion/Ioff ratio of transistors for future high-speed logic applications and also improves the storage capability.Defence Science Journal, 2011, 61(3), pp.235-240, DOI:http://dx.doi.org/10.14429/dsj.61.69

Defect Induced Aging and Breakdown in High-k Dielectrics

abstract: High-k dielectrics have been employed in the metal-oxide semiconductor field effect transistors (MOSFETs) since 45 nm technology node. In this MOSFET industry, Moore’s law projects the feature size of MOSFET scales half within every 18 months. Such scaling down theory has not only led to the physical limit of manufacturing but also raised the reliability issues in MOSFETs. After the incorporation of HfO2 based high-k dielectrics, the stacked oxides based gate insulator is facing rather challenging reliability issues due to the vulnerable HfO2 layer, ultra-thin interfacial SiO2 layer, and even messy interface between SiO2 and HfO2. Bias temperature instabilities (BTI), hot channel electrons injections (HCI), stress-induced leakage current (SILC), and time dependent dielectric breakdown (TDDB) are the four most prominent reliability challenges impacting the lifetime of the chips under use. In order to fully understand the origins that could potentially challenge the reliability of the MOSFETs the defects induced aging and breakdown of the high-k dielectrics have been profoundly investigated here. BTI aging has been investigated to be related to charging effects from the bulk oxide traps and generations of Si-H bonds related interface traps. CVS and RVS induced dielectric breakdown studies have been performed and investigated. The breakdown process is regarded to be related to oxygen vacancies generations triggered by hot hole injections from anode. Post breakdown conduction study in the RRAM devices have shown irreversible characteristics of the dielectrics, although the resistance could be switched into high resistance state.Dissertation/ThesisDoctoral Dissertation Electrical Engineering 201