Efficient simulation and analysis of quantum ballistic transport in nanodevices with AWE

Jun Z. Huang; Weng Cho Chew; Min Tang; Lijun Jiang

doi:10.1109/TED.2011.2176130

Efficient simulation and analysis of quantum ballistic transport in nanodevices with AWE

Jun Z. Huang, Weng Cho Chew, Min Tang, Lijun Jiang

Electrical and Computer Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Quantum-mechanical modeling of ballistic transport in nanodevices usually requires solving the Schrdinger equation at multiple energy points within an energy band. To speed up the simulation and analysis, the asymptotic waveform evaluation is introduced in this paper. Using this method, the wave function is only rigorously solved at several sampled energy points, whereas those at other energies are computed through Pad approximation. This allows us to obtain the physical quantities over the whole energy band with very little computational cost. In addition, the accuracy is controllable by a complex frequency hopping algorithm. The validity and efficiency of the proposed method are demonstrated by detailed study of several multigate silicon nano-MOSFETs.

Original language	English (US)
Article number	6096395
Pages (from-to)	468-476
Number of pages	9
Journal	IEEE Transactions on Electron Devices
Volume	59
Issue number	2
DOIs	https://doi.org/10.1109/TED.2011.2176130
State	Published - Feb 2012

Keywords

Asymptotic waveform evaluation (AWE)
Schrdinger equation
complex frequency hopping (CFH)
local density of states (LDOS)
multigate MOSFET
nanodevices
quantum transport

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Electrical and Electronic Engineering

Online availability

10.1109/TED.2011.2176130

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title = "Efficient simulation and analysis of quantum ballistic transport in nanodevices with AWE",

abstract = "Quantum-mechanical modeling of ballistic transport in nanodevices usually requires solving the Schrdinger equation at multiple energy points within an energy band. To speed up the simulation and analysis, the asymptotic waveform evaluation is introduced in this paper. Using this method, the wave function is only rigorously solved at several sampled energy points, whereas those at other energies are computed through Pad approximation. This allows us to obtain the physical quantities over the whole energy band with very little computational cost. In addition, the accuracy is controllable by a complex frequency hopping algorithm. The validity and efficiency of the proposed method are demonstrated by detailed study of several multigate silicon nano-MOSFETs.",

keywords = "Asymptotic waveform evaluation (AWE), Schrdinger equation, complex frequency hopping (CFH), local density of states (LDOS), multigate MOSFET, nanodevices, quantum transport",

author = "Huang, {Jun Z.} and Chew, {Weng Cho} and Min Tang and Lijun Jiang",

note = "Manuscript received September 15, 2011; revised November 4, 2011; accepted November 8, 2011. Date of publication December 7, 2011; date of current version January 25, 2012. This work was supported in part by the Research Grants Council of Hong Kong (GRF 711609 and 711508), in part by the University Grants Council of Hong Kong (Contract AoE/P-04/08). The review of this paper was arranged by Editor K. Roy.",

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doi = "10.1109/TED.2011.2176130",

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AU - Chew, Weng Cho

AU - Tang, Min

AU - Jiang, Lijun

N1 - Manuscript received September 15, 2011; revised November 4, 2011; accepted November 8, 2011. Date of publication December 7, 2011; date of current version January 25, 2012. This work was supported in part by the Research Grants Council of Hong Kong (GRF 711609 and 711508), in part by the University Grants Council of Hong Kong (Contract AoE/P-04/08). The review of this paper was arranged by Editor K. Roy.

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N2 - Quantum-mechanical modeling of ballistic transport in nanodevices usually requires solving the Schrdinger equation at multiple energy points within an energy band. To speed up the simulation and analysis, the asymptotic waveform evaluation is introduced in this paper. Using this method, the wave function is only rigorously solved at several sampled energy points, whereas those at other energies are computed through Pad approximation. This allows us to obtain the physical quantities over the whole energy band with very little computational cost. In addition, the accuracy is controllable by a complex frequency hopping algorithm. The validity and efficiency of the proposed method are demonstrated by detailed study of several multigate silicon nano-MOSFETs.

AB - Quantum-mechanical modeling of ballistic transport in nanodevices usually requires solving the Schrdinger equation at multiple energy points within an energy band. To speed up the simulation and analysis, the asymptotic waveform evaluation is introduced in this paper. Using this method, the wave function is only rigorously solved at several sampled energy points, whereas those at other energies are computed through Pad approximation. This allows us to obtain the physical quantities over the whole energy band with very little computational cost. In addition, the accuracy is controllable by a complex frequency hopping algorithm. The validity and efficiency of the proposed method are demonstrated by detailed study of several multigate silicon nano-MOSFETs.

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KW - Schrdinger equation

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KW - quantum transport

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Efficient simulation and analysis of quantum ballistic transport in nanodevices with AWE

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