The energy-driven paradigm of NMOSFET hot-carrier effects

Rauch, S.E.; Rosa, G. La

doi:10.1109/tdmr.2005.860560

Cited by 94 publications

(32 citation statements)

References 23 publications

(25 reference statements)

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“…One can see that EES substantially changes the shape of the high-energy tail of the DFs. then used to calculate the carrier acceleration integral (AI)[4,5,[14][15][16] (seeFig. 4).…”

mentioning

confidence: 99%

A predictive physical model for hot-carrier degradation in ultra-scaled MOSFETs

Tyaginov

Bina

Franco

et al. 2014

2014 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD)

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We present and validate a novel physics-based model for hot-carrier degradation. The model incorporates such essential ingredients as a superposition of the multivibrational bond dissociation process and single-carrier mechanism, dispersion of the bond-breakage energy, interaction of the electric field and the dipole moment of the bond, and electron-electron scattering. The main requirement is that the model has to be able to cover HCD observed in a family of MOSFETs of identical architecture but with different gate lengths under diverse stress conditions using a unique set of parameters.

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“…One can see that EES substantially changes the shape of the high-energy tail of the DFs. then used to calculate the carrier acceleration integral (AI)[4,5,[14][15][16] (seeFig. 4).…”

mentioning

confidence: 99%

A predictive physical model for hot-carrier degradation in ultra-scaled MOSFETs

Tyaginov

Bina

Franco

et al. 2014

2014 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD)

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“…A process of electrons tunnel through a barrier in the presence of a high electric field was taken into account by using Fowler-Nordheim model. While, the luckyelectron model provides an estimate of the probability that some carriers in silicon will be transmitted to the oxide by overcoming the local energy barrier at the Si-SiO 2 interface [5][6][7].…”

Section: Methodsmentioning

confidence: 99%

Study of HCI Reliability for PLDMOS

et al. 2018

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In this paper, we demonstrate electrical degradation due to hot carrier injection (HCI) stress for PLDMOS device. The lower gate current and the IDsat degradation at low gate voltage (VGS) and high drain voltage (VDS) is investigated. Hot Electrons, generated by impact ionization during stress, are injected into the gate oxide, creating negative fixed oxide charges and interface-states above the accumulation region and the channel. Increase of the drain-source current is induced by the negative fixed oxide charges. The physical model of the degradation has been proven combining experimental data and TCAD simulations.

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“…For example, the worst HCA used to occur under V g = V d /2 = V dd /2, but HCA of nanodevices under V g = V d = V dd is substantially higher than that under V g = V dd /2 [5], [9], [11]. It is proposed that the HCA of nanodevices is driven by carrier energy and carrier-carrier interaction [11], [14], [16], [17] and multivibration excitation [11] plays important roles. The objective of this paper is to investigate some key issues in characterizing the HCA of nano-nMOSFETs.…”

Section: Introductionmentioning

confidence: 99%

Key Issues and Solutions for Characterizing Hot Carrier Aging of Nanometer Scale nMOSFETs

Duan

Zhang

et al. 2017

IEEE Trans. Electron Devices

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Silicon bandgap limits the reduction of operation voltage when downscaling device sizes. This increases the electrical field within-a-device and hot carrier aging (HCA) is becoming an important reliability issue again for some CMOS technologies. For nanodevices, there are a number of challenges for characterizing their HCA: the random charge-discharge of traps in gate dielectric causes "within-a-device-fluctuation (WDF)," making the parameter shift uncertain after a given HCA. This can introduce errors when extracting HCA time exponents and it will be shown that the lower envelope of the WDF must be used. Nanodevices also have substantial device-to-device variation (DDV) and multiple tests are needed for evaluating their standard deviation (σ) and mean value (μ). Repeating the timeconsuming HCA tests is costly and a voltage-step-stress method is applied to reduce the number of tests by 80%. For a given number of devices under tests (DUTs), there is a little information on the accuracy of the extracted σ and μ. We will develop a method to provide this information, based on the defect-centric model. For 40 DUTs with an average of ten traps per device, the extracted μ and σ has an accuracy of ±14% and ±24%, respectively, with a 95% confidence.

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The energy-driven paradigm of NMOSFET hot-carrier effects

Cited by 94 publications

References 23 publications

A predictive physical model for hot-carrier degradation in ultra-scaled MOSFETs

A predictive physical model for hot-carrier degradation in ultra-scaled MOSFETs

Study of HCI Reliability for PLDMOS

Key Issues and Solutions for Characterizing Hot Carrier Aging of Nanometer Scale nMOSFETs

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