1. Basic features, process dependence and variability of NBTI in p-MOSFETs
1.1. Introduction
1.2. Measurement of NBTI kinetics
1.2.1. Ultra-fast measure-stress-measure method
1.2.2. Time evolution of stress and recovery
1.2.3. Impact of measurement delay
1.2.4. Voltage and temperature dependence
1.2.5. Duty cycle and frequency dependence
1.2.6. Empirical estimation of end-of-life degradation
1.3. Overview of NBTI process dependence
1.3.1. Impact of SiGe channel
1.3.2. Impact of Nitrogen
1.3.3. Impact of gate stack thickness scaling
1.3.4. Impact of fin dimension scaling
1.3.5. Impact of layout
1.4. NBTI in small area devices
1.4.1. Stress and recovery kinetics
1.4.2. Distribution of degradation
1.4.3. Correlation of variability and variable NBTI
1.4.4. Random Telegraph Noise
1.5. Physical mechanism of NBTI - an overview
1.6. Summary
2. NBTI kinetics modeling framework
2.1. Introduction
2.2. Overview of NBTI modeling framework
2.3. Generation and passivation of interface traps
2.3.1. Double interface Reaction-Diffusion (RD) model
2.3.2. Physical mechanism of defect depassivation
2.3.3. A discussion on RD model parameters
2.3.4. DCIV measurement method
2.3.5. Prediction of DCIV data
2.3.6. Analysis of Ge% and N% impact
2.3.7. Comparison of continuum and stochastic frameworks
2.4. Occupancy of generated interface traps
2.4.1. Transient Trap Occupancy Model (TTOM)
2.4.2. Validation of TTOM framework
2.5. Hole trapping in pre-existing bulk traps
2.6. Validation of TTOM enabled RD and hole trapping
2.7. Time Dependent Defect Spectroscopy (TDDS) analysis
2.8. Generation of bulk traps
2.9. Validation of TTOM enabled RD and bulk trap generation
2.10. Summary
3. Modeling of NBTI kinetics in HKMG Si and Si-capped SiGe p-MOSFETs
3.1. Introduction
3.2. Description of process splits
3.3. Analysis of Gate First HKMG planar devices
3.3.1. DC stress and recovery kinetics
3.3.2. Impact of measurement delay
3.3.3. Nitrogen impact on NBTI parameters
3.3.4. AC stress kinetics
3.4. Analysis of mean stress-recovery kinetics from small area devices
3.5. Process dependence of model parameters
3.6. Estimation of end-of-life degradation
3.6.1. Calculation by empirical method
3.6.2. Calculation by physical model
3.6.3. Comparison of empirical and physical methods
3.7. Analysis of Si-capped SiGe planar devices
3.7.1. Stress and recovery kinetics
3.7.2. Voltage acceleration factor
3.7.3. Process dependence of model parameters
3.7.4. Estimation of end-of-life degradation
3.8. Summary
4. Modeling of NBTI kinetics in HKMG Si and SiGe FDSOI MOSFETs
4.1. Introduction
4.2. Description of process splits
4.3. Analysis of measured data
4.3.1. Time kinetics of stress and recovery
4.3.2. Impact of Ge% and N%
4.3.3. Impact of layout (STI to active spacing)
4.3.4. Process dependence of model parameters
4.4. Explanation of process dependence
4.4.1. Impact of Ge% and N%
4.4.2. Impact of layout effect
4.5. Estimation of end-of-life degradation
4.6. Summary
Souvik Mahapatra received his Bachelors and Masters degrees in Physics from Jadavpur University, Calcutta, India in 1993 and 1995 respectively, and PhD in Electrical Engineering from IIT Bombay, Mumbai, India in 1999. During 2000-2001, he was with Bell Laboratories, Lucent Technolgies, Murray Hill, NJ, USA. Since 2002 he is with IIT Bombay, and is currently the PK Kelkar Chair Professor in the Department of Electrical Engineering. His primary research interests are in the areas of semiconductor device characterization, modeling and simulation, and in particular, MOS transistor and Flash memory device scaling and reliability. He has interacted closely with major semiconductor industries in the world, and has contributed in several technologically relevant research topics such as MOS gate insulator scaling, Bias Temperature Instability and Hot Carrier Degradation in CMOS devices, CHISEL NOR Flash, SONOS NOR and NAND Flash memory devices. He has authored and co-authored more than 190 papers in peer reviewed journals and conferences and several book chapters, and delivered invited talks and tutorials in major international conferences around the world, including at the IEEE IEDM and IEEE IRPS. He has served as a distinguished lecturer of the IEEE EDS, chair of the IEEE EDS device reliability physics subcommittee, and in paper selection subcommittees and as session chairs in several IEEE conferences. He is a fellow of Institute of Electrical and Electronics Engineers (IEEE), Indian National Science Academy (INSA), Indian National Academy of Engineering (INAE) and Indian Academy of Sciences (IASc).