Simulation of intrinsic parameter fluctuations in decananometer and nanometer-scale MOSFETs

Asenov, A.; Brown, Andrew R.; Davies, John H.; Kaya, Savaş; Slavcheva, G

doi:10.1109/ted.2003.815862

Cited by 504 publications

(260 citation statements)

References 92 publications

(134 reference statements)

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“…[2][3][4][5] Achievements include controlled positioning of small numbers of dopants within the semiconducting host, 4,6-9 with quantitative theoretical descriptions of their wave functions, 10,11 as well as local perturbations of their properties including optical orientation of their spin, 12 electrical control of their charge state, 13,14 and electrical probing of their spin excitations. 15 Electronic manipulation of dopant charge states has been predominately limited to ionization of Coulombically bound (shallow) donor and acceptor levels, 14,16 although switching a Si dopant between a substitutional and interstitial position with an associated charge change has also been demonstrated.…”

Section: Introductionmentioning

confidence: 99%

Core-state manipulation of single Fe impurities in GaAs with a scanning tunneling microscope

et al. 2013

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The incorporation of Fe in GaAs was studied by cross-sectional scanning tunneling microscopy (X-STM). The observed local electronic contrast of a single Fe atom is found to depend strongly on its charge state. We demonstrate that an applied tip voltage can be used to manipulate the valence and spin state of single Fe impurities in GaAs. In particular we can induce a transition from the (Fe 3+ ) 0 -3d 5 -isoelectronic state to the (Fe 2+ ) − -3d 6 -ionized acceptor state with an associated change of the spin moment. Fe atoms sometimes produce dark anisotropic features in topographic maps, which is consistent with an interference between different tunneling paths.[1] P.M. Koenraad and M. E. Flatté, Nature Materials 10, 91 (2011).

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Section: Introductionmentioning

confidence: 99%

Core-state manipulation of single Fe impurities in GaAs with a scanning tunneling microscope

et al. 2013

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“…Low frequency noise has been reported [6] of an amplitude comparable with 20-60% of the drain current. Current fluctuations on this scale become a serious performance and reliability issue.…”

Section: Mosfet Technologymentioning

confidence: 97%

“…The CRBM is based on Hinton's Product of Expert in Restricted Boltzmann Machine form (PoE/RBM) [4], adapted to draw upon the training approach of the diffusion network [5]. We adopt a hierarchical modeling strategy, whereby we first (Section 3.1) build SPICE-based behavioral models of noisy DSM MOSFETs based upon "atomistic" simulation of the underlying noise mechanisms [6]. We then design the key component of the CRBM, an analog multiplier, using noisy-MOSFET models (Section 3.2).…”

Section: Introductionmentioning

confidence: 99%

Probabilistic Computing with Future Deep Sub-Micrometer Devices: A Modelling Approach

Hamid

Murray

Laurenson

et al.

2005 IEEE International Symposium on Circuits and Systems

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Abstract-An approach is described that investigates the potential of probabilistic "neural" architectures for computation with Deep Sub-Micrometer (DSM) MOSFETs. Initially, noisy MOSFET models are based upon those for a 0.35µm MOS technology with an exaggerated 1/f characteristic. We explore the manifestation of the 1/f characteristic at the output of 2-quadrant multiplier when the key n-channel MOSFETs are replaced by "noisy" MOSFETs. The stochastic behavior of this noisy multiplier has been mapped on to a software (Matlab) model of a Continuous Restricted Boltzmann Machine (CRBM) -an analogue-input stochastic computing structure. Simulation of this DSM CRBM implementation shows little degradation from that of a "perfect" CRBM. This paper thus introduces a methodology for a form of "technology-downstreaming" and highlights the potential of probabilistic architectures for DSM computation.

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“…Circuit and system performance and yield will be greatly affected at future generation technology nodes, and the analysis of such variations is vital for the continued advancement of the silicon industry. Various intrinsic sources of parameter fluctuations have been studied up to this point, including random discrete doping, line edge roughness and oxide thickness variation [1,2].…”

Section: Introductionmentioning

confidence: 99%

Capacitance fluctuations in bulk MOSFETs due to random discrete dopants

Brown

Asenov

2008

J Comput Electron

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Accuracy of timing in circuits and systems using nanoscale transistors is crucial and is dependent, to first order, on the capacitances of the load transistors. It is accepted that variation in parameters will be intrinsic to such devices due to, among other factors, the discrete nature of the doping. It is likely that one such parameter exhibiting variation will be capacitance. Here we investigate, using 3-dimensional simulation, the fluctuation in gate and drain capacitance in a 30 nm MOSFET due to random discrete doping.

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Simulation of intrinsic parameter fluctuations in decananometer and nanometer-scale MOSFETs

Cited by 504 publications

References 92 publications

Core-state manipulation of single Fe impurities in GaAs with a scanning tunneling microscope

Core-state manipulation of single Fe impurities in GaAs with a scanning tunneling microscope

Probabilistic Computing with Future Deep Sub-Micrometer Devices: A Modelling Approach

Capacitance fluctuations in bulk MOSFETs due to random discrete dopants

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