![Fig. 5. Time evolution of (normalized) drain current shift for PMOS inversion and NMOS accumulation NBTI stress. Degradation at low VG for all time and high VG at shorter time is due to interface-trap generation, while long-time enhanced degradation at high VG is due to bulk-trap generation [15,16]. Under identical oxide field ðVGjinv ¼ VGjacc 1 V to account for difference in flatband voltage) PMOS inversion and NMOS accumulation (short time) stress show similar degradation, which characterizes the role of holes for NBTI.](/figures/fig-5-time-evolution-of-normalized-drain-current-shift-for-25rnsgi7.webp)
![Fig. 7. Experimental and theoretical time evolution of threshold voltage shift data for a wide range of stress VG. The calculated bulk trap contributions are shown by dashed lines [15]. Theory matches well with experiment. Bulk trap generation at large oxide fields (high VG) affects overall threshold voltage shift and must be taken into account for properly estimating the forward reaction rate of the R–D model.](/figures/fig-7-experimental-and-theoretical-time-evolution-of-2fr9nut9.webp)
![Fig. 9. Temperature activation of 1=tBREAK and DH. The DH is calculated from the universal scaling of temperature dependent (fixed oxide field) generated interface trap data. Obtained activation energy supports neutral H2 diffusion [32].](/figures/fig-9-temperature-activation-of-1-tbreak-and-dh-the-dh-is-2c3pb1to.webp)
Q2. What are the future works mentioned in the paper "A comprehensive model of pmos nbti degradation" ?
One of the key goal of their future work would be to clarify the role of such processing changes on NBTI performance.
A comprehensive model of PMOS NBTI degradation
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TLDR
A comprehensive model for NBTI phenomena within the framework of the standard reaction–diffusion model is constructed and it is demonstrated how to solve the reaction-diffusion equations in a way that emphasizes the physical aspects of the degradation process and allows easy generalization of the existing work.About:
This article is published in Microelectronics Reliability.The article was published on 2005-01-01 and is currently open access. It has received 710 citations till now. The article focuses on the topics: Negative-bias temperature instability.read more
Figures
![Fig. 5. Time evolution of (normalized) drain current shift for PMOS inversion and NMOS accumulation NBTI stress. Degradation at low VG for all time and high VG at shorter time is due to interface-trap generation, while long-time enhanced degradation at high VG is due to bulk-trap generation [15,16]. Under identical oxide field ðVGjinv ¼ VGjacc 1 V to account for difference in flatband voltage) PMOS inversion and NMOS accumulation (short time) stress show similar degradation, which characterizes the role of holes for NBTI.](/figures/fig-5-time-evolution-of-normalized-drain-current-shift-for-25rnsgi7.png)
Fig. 5. Time evolution of (normalized) drain current shift for PMOS inversion and NMOS accumulation NBTI stress. Degradation at low VG for all time and high VG at shorter time is due to interface-trap generation, while long-time enhanced degradation at high VG is due to bulk-trap generation [15,16]. Under identical oxide field ðVGjinv ¼ VGjacc 1 V to account for difference in flatband voltage) PMOS inversion and NMOS accumulation (short time) stress show similar degradation, which characterizes the role of holes for NBTI. 
Fig. 6. Voltage- and field-acceleration factors (cV and cE, respectively) plotted as a function of oxide thickness. The thickness independence of the field acceleration factor suggests lifetime of the form s expðcEEOXÞ. Since NIT sn, therefore NIT expðEOX=E0Þ with E0 ¼ 1=ncE is the form that describes the NBTI data well. ![Fig. 7. Experimental and theoretical time evolution of threshold voltage shift data for a wide range of stress VG. The calculated bulk trap contributions are shown by dashed lines [15]. Theory matches well with experiment. Bulk trap generation at large oxide fields (high VG) affects overall threshold voltage shift and must be taken into account for properly estimating the forward reaction rate of the R–D model.](/figures/fig-7-experimental-and-theoretical-time-evolution-of-2fr9nut9.png)
Fig. 7. Experimental and theoretical time evolution of threshold voltage shift data for a wide range of stress VG. The calculated bulk trap contributions are shown by dashed lines [15]. Theory matches well with experiment. Bulk trap generation at large oxide fields (high VG) affects overall threshold voltage shift and must be taken into account for properly estimating the forward reaction rate of the R–D model. 
Fig. 1. (a) Schematic description of the reaction–diffusion model u Broken Si–H bonds at the Si–SiO2 interface create Si þ (interface trap bond dissociation (reaction), while the later rate depends on H remo diffuser, H removal is triggered by H2 diffusion (see Section 3). (b) Hy the hydrogen profile equals generated interface traps (see Section 2). limited (1,2) and diffusion-limited (3,4) regimes. Once the diffusion fro poly ensures that the concentration of H2 at the poly-oxide interface w in the hydrogen profile resulting in faster H removal from the Si/oxide 
Fig. 8. (a) Universal scaling scheme for generated interface traps versus time data. Density axis reflects higher Si–H bond dissociation (reaction) while time axis denotes faster hydrogen diffusion. Assuming neutral diffusion species, the reaction and diffusion components can be independently scaled by voltage dependent (time independent) and time dependent (voltage independent) functions respectively. (b) Universality of scaled generated interface traps versus time data. Data taken under a wide bias and temperature range validates the scaling hypothesis. ![Fig. 9. Temperature activation of 1=tBREAK and DH. The DH is calculated from the universal scaling of temperature dependent (fixed oxide field) generated interface trap data. Obtained activation energy supports neutral H2 diffusion [32].](/figures/fig-9-temperature-activation-of-1-tbreak-and-dh-the-dh-is-2c3pb1to.png)
Fig. 9. Temperature activation of 1=tBREAK and DH. The DH is calculated from the universal scaling of temperature dependent (fixed oxide field) generated interface trap data. Obtained activation energy supports neutral H2 diffusion [32].
Citations
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Proceedings ArticleDOI
Accurate description of temperature accelerated NBTI effect using the universal prediction model
Fu Sun,Chenyue Ma,Xinnan Lin +2 more
TL;DR: In this article, the temperature accelerated NBTI effect is modeled by a universal model, which reveals distinct degradation mechanisms under low and high temperatures, which is supposed due to the influence of temperature to the Si-H bond activation energy and H 2 diffusivity.
Proceedings ArticleDOI
Diagnostic Circuit for Latent Fault Detection in SRAM Row Decoder
TL;DR: A novel technology-agnostic diagnostic test circuit and method is proposed to detect small resistive defects as low as $5\mathrm{K}\Omega$ before they can result in functional failure.
Journal Article
Novel NBTI Aware Approach for Low Power FinFET Based Wide Fan-In Domino Logic.
Vikas Mahor,Manisha Pattanaik +1 more
Journal ArticleDOI
An efficient NBTI-aware wake-up strategy: Concept, design, and manipulation
TL;DR: A novel reconfigurable circuit structure that can reconfigure thewake-up sequence and a novel NBTI-aware wake-up strategy to reduce the wake- up time are proposed.
References
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Harvey Scher,Elliott W. Montroll +1 more
TL;DR: In this paper, the authors developed a stochastic transport model for the transient photocurrent, which describes the dynamics of a carrier packet executing a time-dependent random walk in the presence of a field-dependent spatial bias and an absorbing barrier at the sample surface.
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Negative bias temperature instability: Road to cross in deep submicron silicon semiconductor manufacturing
TL;DR: The negative bias temperature instability (NBTI) commonly observed in p-channel metaloxide-semiconductor field effect transistors when stressed with negative gate voltages at elevated temperatures is discussed in this article.
Journal ArticleDOI
Negative bias stress of MOS devices at high electric fields and degradation of MNOS devices
Kjell Jeppson,Christer Svensson +1 more
TL;DR: A detailed study of the increase of the number of surface traps in MOS structures after NBS at temperatures (25-125°C) and fields (400-700 MV/m) comparable to those used in MNOS devices is presented in this article.
Journal ArticleDOI
Characteristics of the Surface‐State Charge (Qss) of Thermally Oxidized Silicon
TL;DR: In this paper, the surface state charge associated with thermally oxidized silicon has been studied experimentally using MOS structures and the results indicate that the surface-state charge can be reproducibly controlled over a range 1010-1012 cm -2, and it is an intrinsic property of the silicon dioxide-silicon system.
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