Surface Potential Modelling of Hot Carrier Degradation in CMOS Technology

abstract: The scaling of transistors has numerous advantages such as increased memory density, less power consumption and better performance; but on the other hand, they also give rise to many reliability issues. One of the major reliability issue is the hot carrier injection and the effect it has on device degradation over time which causes serious circuit malfunctions. Hot carrier injection has been studied from early 1980's and a lot of research has been done on the various hot carrier injection mechanisms and how the devices get damaged due to this effect. However, most of the existing hot carrier degradation models do not consider the physics involved in the degradation process and they just calculate the change in threshold voltage for different stress voltages and time. Based on this, an analytical expression is formulated that predicts the device lifetime. This thesis starts by discussing various hot carrier injection mechanisms and the effects it has on the device. Studies have shown charges getting trapped in gate oxide and interface trap generation are two mechanisms for device degradation. How various device parameters get affected due to these traps is discussed here. The physics based models such as lucky hot electron model and substrate current model are presented and gives an idea how the gate current and substrate current can be related to hot carrier injection and density of traps created. Devices are stressed under various voltages and from the experimental data obtained, the density of trapped charges and interface traps are calculated using mid-gap technique. In this thesis, a simple analytical model based on substrate current is used to calculate the density of trapped charges in oxide and interface traps generated and it is a function of stress voltage and stress time. The model is verified against the data and the TCAD simulations. Finally, the analytical model is incorporated in a Verilog-A model and based on the surface potential method, the threshold voltage shift due to hot carrier stress is calculated.Dissertation/ThesisMasters Thesis Electrical Engineering 201

Simulation study of scaling design, performance characterization, statistical variability and reliability of decananometer MOSFETs

This thesis describes a comprehensive, simulation based scaling study – including device design, performance characterization, and the impact of statistical variability – on deca-nanometer bulk MOSFETs. After careful calibration of fabrication processes and electrical characteristics for n- and p-MOSFETs with 35 nm physical gate length, 1 nm EOT and stress engineering, the simulated devices closely match the performance of contemporary 45 nm CMOS technologies. Scaling to 25 nm, 18 nm and 13 nm gate length n and p devices follows generalized scaling rules, augmented by physically realistic constraints and the introduction of high-k/metal-gate stacks. The scaled devices attain the performance stipulated by the ITRS. Device a.c. performance is analyzed, at device and circuit level. Extrinsic parasitics become critical to nano-CMOS device performance. The thesis describes device capacitance components, analyzes the CMOS inverter, and obtains new insights into the inverter propagation delay in nano-CMOS. The projection of a.c. performance of scaled devices is obtained. The statistical variability of electrical characteristics, due to intrinsic parameter fluctuation sources, in contemporary and scaled decananometer MOSFETs is systematically investigated for the first time. The statistical variability sources: random discrete dopants, gate line edge roughness and poly-silicon granularity are simulated, in combination, in an ensemble of microscopically different devices. An increasing trend in the standard deviation of the threshold voltage as a function of scaling is observed. The introduction of high-k/metal gates improves electrostatic integrity and slows this trend. Statistical evaluations of variability in Ion and Ioff as a function of scaling are also performed. For the first time, the impact of strain on statistical variability is studied. Gate line edge roughness results in areas of local channel shortening, accompanied by locally increased strain, both effects increasing the local current. Variations are observed in both the drive current, and in the drive current enhancement normally expected from the application of strain. In addition, the effects of shallow trench isolation (STI) on MOSFET performance and on its statistical variability are investigated for the first time. The inverse-narrow-width effect of STI enhances the current density adjacent to it. This leads to a local enhancement of the influence of junction shapes adjacent to the STI. There is also a statistical impact on the threshold voltage due to random STI induced traps at the silicon/oxide interface

DEEP SUBMICRON CMOS VLSI CIRCUIT RELIABILITY MODELING, SIMULATION AND DESIGN

CMOS VLSI circuit reliability modeling and simulation have attracted intense research interest in the last two decades, and as a result almost all IC Design For Reliability (DFR) tools now try to incrementally simulate device wearout mechanisms in iterative ways. These DFR tools are capable of accurately characterizing the device wearout process and predicting its impact on circuit performance. Nevertheless, excessive simulation time and tedious parameter testing process often limit popularity of these tools in product design and fabrication. This work develops a new SPICE reliability simulation method that shifts the focus of reliability analysis from device wearout to circuit functionality. A set of accelerated lifetime models and failure equivalent circuit models are proposed for the most common MOSFET intrinsic wearout mechanisms, including Hot Carrier Injection (HCI), Time Dependent Dielectric Breakdown (TDDB), and Negative Bias Temperature Instability (NBTI). The accelerated lifetime models help to identify the most degraded transistors in a circuit in terms of the device's terminal voltage and current waveforms. Then corresponding failure equivalent circuit models are incorporated into the circuit to substitute these identified transistors. Finally, SPICE simulation is performed again to check circuit functionality and analyze the impact of device wearout on circuit operation. Device wearout effects are lumped into a very limited number of failure equivalent circuit model parameters, and circuit performance degradation and functionality are determined by the magnitude of these parameters. In this new method, it is unnecessary to perform a large number of small-step SPICE simulation iterations. Therefore, simulation time is obviously shortened in comparison to other tools. In addition, a reduced set of failure equivalent circuit model parameters, rather than a large number of device SPICE model parameters, need to be accurately characterized at each interim wearout process. Thus device testing and parameter extraction work are also significantly simplified. These advantages will allow circuit designers to perform quick and efficient circuit reliability analyses and to develop practical guidelines for reliable electronic designs

ランダム・テレグラフ・ノイズの微細MOSFETへの影響に関する研究

筑波大学 (University of Tsukuba)201

Stress-induced leakage current in dual-gate CMOSFETS with thin nitrided gate oxides

Master'sMASTER OF ENGINEERIN

Study Of Nanoscale Cmos Device And Circuit Reliability

The development of semiconductor technology has led to the significant scaling of the transistor dimensions -The transistor gate length drops down to tens of nanometers and the gate oxide thickness to 1 nm. In the future several years, the deep submicron devices will dominate the semiconductor industry for the high transistor density and the corresponding performance enhancement. For these devices, the reliability issues are the first concern for the commercialization. The major reliability issues caused by voltage and/or temperature stress are gate oxide breakdown (BD), hot carrier effects (HCs), and negative bias temperature instability (NBTI). They become even more important for the nanoscale CMOS devices, because of the high electrical field due to the small device size and high temperature due to the high transistor densities and high-speed performances. This dissertation focuses on the study of voltage and temperature stress-induced reliability issues in nanoscale CMOS devices and circuits. The physical mechanisms for BD, HCs, and NBTI have been presented. A practical and accurate equivalent circuit model for nanoscale devices was employed to simulate the RF performance degradation in circuit level. The parameter measurement and model extraction have been addressed. Furthermore, a methodology was developed to predict the HC, TDDB, and NBTI effects on the RF circuits with the nanoscale CMOS. It provides guidance for the reliability considerations of the RF circuit design. The BD, HC, and NBTI effects on digital gates and RF building blocks with the nanoscale devices low noise amplifier, oscillator, mixer, and power amplifier, have been investigated systematically. The contributions of this dissertation include: It provides a thorough study of the reliability issues caused by voltage and/or temperature stresses on nanoscale devices from device level to circuit level; The more real voltage stress case high frequency (900 MHz) dynamic stress, has been first explored and compared with the traditional DC stress; A simple and practical analytical method to predict RF performance degradation due to voltage stress in the nanoscale devices and RF circuits was given based on the normalized parameter degradations in device models. It provides a quick way for the designers to evaluate the performance degradations; Measurement and model extraction technologies, special for the nanoscale MOSFETs with ultra-thin, ultra-leaky gate oxide, were addressed and employed for the model establishments; Using the present existing computer-aided design tools (Cadence, Agilent ADS) with the developed models for performance degradation evaluation due to voltage or/and temperature stress by simulations provides a potential way that industry could use to save tens of millions of dollars annually in testing costs. The world now stands at the threshold of the age of nanotechnology, and scientists and engineers have been exploring here for years. The reliability is the first challenge for the commercialization of the nanoscale CMOS devices, which will be further downscaling into several tens or ten nanometers. The reliability is no longer the post-design evaluation, but the pre-design consideration. The successful and fruitful results of this dissertation, from device level to circuit level, provide not only an insight on how the voltage and/or temperature stress effects on the performances, but also methods and guidance for the designers to achieve more reliable circuits with nanoscale MOSFETs in the future

Compact Models for Integrated Circuit Design

This modern treatise on compact models for circuit computer-aided design (CAD) presents industry standard models for bipolar-junction transistors (BJTs), metal-oxide-semiconductor (MOS) field-effect-transistors (FETs), FinFETs, and tunnel field-effect transistors (TFETs), along with statistical MOS models. Featuring exercise problems at the end of each chapter and extensive references at the end of the book, the text supplies fundamental and practical knowledge necessary for efficient integrated circuit (IC) design using nanoscale devices. It ensures even those unfamiliar with semiconductor physics gain a solid grasp of compact modeling concepts

Hot carrier degradation in deep submicron n-MOS technologies

With the aggressive scaling of MOS devices hot carrier degradation continues to be a major reliability concern. The LDD technologies, which have been used to minimise the hot carrier damage in MOS devices, suffer from the spacer damage causing the drain series resistance degradation, along with the channel mobility degradation. Therefore, in order to optimise the performance and reliability of these technologies it is necessary to quantify the roles of spacer and channel damages in determining their degradation behaviour. In this thesis the hot carrier degradation behaviour of different generations of graded drain (lightly doped, mildly doped and highly doped) n-MOS technologies, designed for 5V, 3V and 2V operation is investigated. The stress time beginning from microseconds is investigated to study how the damage initiates and evolves over time. A technology dependent two-stage degradation behaviour in the measured transconductance with an early stage deviating from conventionally observed power law behaviour is reported. A methodology based on conventional extraction procedure using the L-array method is first developed to analyse the drain series resistance and the mobility degradation. For 5V technologies the analysis of the damage using this methodology shows a two-stage drain series resistance degradation with early stage lasting about lOOms. However, it is seen that the conventional series resistance and mobility degradation methodology fails to satisfactorily predict degradation behaviour of 3V and 2V technologies, resulting in unphysical decreasing extracted series resistance. It is shown that after the hot carrier stress a change in the universal mobility behaviour for channel lengths approaching quarter micron regime has a significant effect on the parameter extraction. A modified universal mobility model incorporating the effect of the interface charge is developed using the FN stress experiments. A new generalised extraction methodology modelling hot carrier stressed device as series combination of undamaged and damaged channel regions, along with the series source drain resistance is developed, incorporating the modified universal model in the damaged channel region. The new methodology has the advantage of being single device based and serves as an effective tool in evaluating. the roles of series resistance and mobility degradations for technology qualification. This is especially true for the deep submicron regime where the conventional extraction procedures are not applicable. Further, the new extraction method has the potential of being integrated into commercial device simulation tools, to accurately analyse the device degradation behaviour in deep submicron regime

EXPERIMENTAL STUDY OF BIAS TEMPERATURE INSTABILITY AND PROGRESSIVE BREAKDOWN OF ADVANCED GATE DIELECTRICS

With shrinking gate dielectrics, the reliability requirements of semiconductor gate dielectrics become more and more difficult to maintain. New physical mechanisms and phenomena are discovered and new challenges arise. At the same time, some issues, which have been minor in the past, begin to show bigger impact, such as the Negative Bias Temperature Instability issue. The dynamic NBTI phenomenon was studied with ultrathin SiO2 and HfO2 devices. With a dynamic stress condition, the device lifetime can be largely extended due to the reduced NBTI degradation. This reduction is contributed to the annealing of fixed oxide charges during the stress off period. A mathematical model is also established to explain this phenomenon. With alternative gate dielectrics' introduction, new issues associated with these materials and device structures are also raised. Those issues need to be studied in detail before fully incorporation of new materials. Compared with SiO2 devices, the NBTI degradation of HfO2 has a similar trend. However, it is found that they have different frequency response than the SiO2 devices. This difference is later found due to the traps inside the gate dielectrics. Detailed studies show that NBTI degradations at dc stress and dynamic stress conditions have different temperature acceleration factors due to the bulk traps. The disappearance of this difference by insetting a detrapping period further proves this observation. As we enter the ultrathin gate dielectrics regime, the electron tunneling mechanisms behind the gate dielectrics breakdown shift. Consequently, gate dielectrics breakdown mode also shifts from the clear-detected hard breakdown to the noisy soft breakdown. Thus new lifetime extrapolation models are needed. The progressive breakdown of ultrathin SiO2 is studied by a two-step test methodology. By monitoring the degradation of the progressive breakdown path in terms of the activation energy, the voltage acceleration factor, two kinds of breakdown filaments, the stable one and the unstable one, were studied. The stable filament is found to be a breakdown filament independent of the original breakdown filament, and the unstable filament is the continuing degradation of the original filament