Quantitative Evaluation of Statistical Variability Sources in a 45-nm Technological Node LP N-MOSFET

Cathignol, A.; Cheng, Binjie; Chanemougame, D.; Brown, Andrew R.; Rochereau, K.; Ghibaudo, G.; Asenov, A.

doi:10.1109/led.2008.922978

Cited by 78 publications

(29 citation statements)

References 15 publications

(18 reference statements)

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“…[1][2][3][4][5] Properties of electrode/NW contact-interfaces are of particular interest [6][7][8][9][10] due to the potential application of quasi-one-dimensional materials into future nanosensing and nanoelectronic devices. 11 It has been proposed by theory that Fermi level pinning effects, which frequently hinder the performance of planar devices, 12 are expected to be strongly reduced in side contacts to NW channels due to their confined geometry. 13,14 Although several studies regarding the contact-resistivity in semiconducting NW devices can be found, [6][7][8][9][10] an analysis addressing both the contact-interface properties and also verifying the plausibility of common bulk-based extrapolation methods is to-date not presented.…”

mentioning

confidence: 99%

Contact resistivity and suppression of Fermi level pinning in side-contacted germanium nanowires

Koleśnik-Gray

Lutz

Collins

et al. 2013

Applied Physics Letters

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Electrical properties of contact-interfaces in germanium nanowire field effect transistor devices are studied. In contrast to planar bulk devices, it is shown that the active conduction channel and gate length extend between and underneath the contact electrodes. Furthermore, direct scaling of contact resistivity and Schottky barrier height with electrode metal function is observed. The associated pinning parameter was found to be γ=0.65 ± 0.03γ=0.65 ± 0.03, which demonstrates a significant suppression of Fermi level pinning in quasi-one-dimensional structures

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mentioning

confidence: 99%

Contact resistivity and suppression of Fermi level pinning in side-contacted germanium nanowires

Koleśnik-Gray

Lutz

Collins

et al. 2013

Applied Physics Letters

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“…The simulator is meticulously calibrated and validated in respect of statistical variability simulations and measurements at 45/40 nm [19], and at 32/28 nm technology generations [14]. It has been demonstrated that that RDD, LER and MGG are major statistical variability sources in 32/28nm high-k/metal gate bulk CMOS technology.…”

Section: Simulation Methodologymentioning

confidence: 99%

“…This is based on meticulous validation of our simulation technology in respect of 45/40 nm [19] and 32/28-nm technology [14]. This paper also goes beyond most of the previously published simulation and measurement results, reporting a systematic study on the impact of geometry, substrate bias and temperature on the statistical variability of carefully designed 'template' 25 nm gate-length MOSFETs meeting the specifications of 20 nm CMOS.…”

Section: Introductionmentioning

confidence: 97%

Geometry, Temperature, and Body Bias Dependence of Statistical Variability in 20-nm Bulk CMOS Technology: A Comprehensive Simulation Analysis

Wang

Adamu-Lema

Cheng

et al. 2013

IEEE Trans. Electron Devices

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Abstract-Conventional bulk CMOS, which is arguably most vulnerable to statistical variability, has been the workhorse of the electronic industry for more than three decades. In this paper, the dependence of the statistical variability of key figures of merit on gate geometry, temperature and body bias in 25nm gate-length MOSFETs, representative for the 20nm CMOS technology generation, are systematically investigated using 3D statistical simulations. The impact of all relevant sources of statistical variability is taken into account. The geometry dependence of the threshold voltage dispersion (and indeed the dispersion of other key transistor figures of merit) does not necessarily follow the Pelgrom's law due to the complex non-uniform channel doping and the interplay of different statistical-variability sources. The DIBL variation for example follows a log-normal distribution. The temperature significantly affects the magnitudes of threshold-voltage, sub-threshold slope, on/off currents and the corresponding statistical distributions. Reverse body bias increases the threshold voltage and its fluctuation while forward body bias reduces both of them.

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“…Details about the device structure and doping profiles are published elsewhere [12,13]. We simulate NBTI variability associated with fixed/trapped random positive charges in concert with all other variability sources relevant for this technology.…”

Section: Simulation Methodologymentioning

confidence: 99%

Statistical aspects of NBTI/PBTI and impact on SRAM yield

Asenov

Brown

Cheng

2011

2011 Design, Automation &Amp; Test in Europe

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Abstract-Quantitative simulations of the statistical impact of negative-bias-temperature-instability (NBTI) on pMOSFETs, and positive-bias-temperature-instability (PBTI) on nMOSFETs are carried out for a 45nm low power technology generation. Based on the statistical simulation results, we investigate the impact of NBTI and PBTI on the degradation of the static noise margin (SNM) of SRAM cells. The results indicate that SNM degradation due only to NBTI follows a different evolution pattern compared with the impact of simultaneous NBTI and PBTI degradation.

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Quantitative Evaluation of Statistical Variability Sources in a 45-nm Technological Node LP N-MOSFET

Cited by 78 publications

References 15 publications

Contact resistivity and suppression of Fermi level pinning in side-contacted germanium nanowires

Contact resistivity and suppression of Fermi level pinning in side-contacted germanium nanowires

Geometry, Temperature, and Body Bias Dependence of Statistical Variability in 20-nm Bulk CMOS Technology: A Comprehensive Simulation Analysis

Statistical aspects of NBTI/PBTI and impact on SRAM yield

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