Time-dependent Quantum Waveguide Theory: A Study of Nano Ring Structures

S.D. Midgley; Jingbo Wang

Time-dependent Quantum Waveguide Theory: A Study of Nano Ring Structures

S.D. Midgley, Jingbo Wang

Graduate Research School

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

13 Citations (Scopus)

Abstract

As electronic circuits get progressingly smaller to the nanometre scale, the quantum wave nature of the electrons starts to play a dominant role. It is thus possible for the devices to operate by controlling the phase of the quantum electron waves rather than the electron density as in present-day devices. This paper presents a highly accurate numerical method to treat quantum waveguides with arbitrarily complex geometry. Based on this model, a variety of quantum erects can be studied and quantified.

Original language	English
Pages (from-to)	77-85
Journal	Australian Journal of Physics
Volume	53
Publication status	Published - 2000

Cite this

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title = "Time-dependent Quantum Waveguide Theory: A Study of Nano Ring Structures",

abstract = "As electronic circuits get progressingly smaller to the nanometre scale, the quantum wave nature of the electrons starts to play a dominant role. It is thus possible for the devices to operate by controlling the phase of the quantum electron waves rather than the electron density as in present-day devices. This paper presents a highly accurate numerical method to treat quantum waveguides with arbitrarily complex geometry. Based on this model, a variety of quantum erects can be studied and quantified.",

author = "S.D. Midgley and Jingbo Wang",

year = "2000",

language = "English",

volume = "53",

pages = "77--85",

journal = "Australian Journal of Physics",

issn = "0004-9506",

publisher = "Blackwell",

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T1 - Time-dependent Quantum Waveguide Theory: A Study of Nano Ring Structures

AU - Midgley, S.D.

AU - Wang, Jingbo

PY - 2000

Y1 - 2000

N2 - As electronic circuits get progressingly smaller to the nanometre scale, the quantum wave nature of the electrons starts to play a dominant role. It is thus possible for the devices to operate by controlling the phase of the quantum electron waves rather than the electron density as in present-day devices. This paper presents a highly accurate numerical method to treat quantum waveguides with arbitrarily complex geometry. Based on this model, a variety of quantum erects can be studied and quantified.

AB - As electronic circuits get progressingly smaller to the nanometre scale, the quantum wave nature of the electrons starts to play a dominant role. It is thus possible for the devices to operate by controlling the phase of the quantum electron waves rather than the electron density as in present-day devices. This paper presents a highly accurate numerical method to treat quantum waveguides with arbitrarily complex geometry. Based on this model, a variety of quantum erects can be studied and quantified.

M3 - Article

SN - 0004-9506

VL - 53

SP - 77

EP - 85

JO - Australian Journal of Physics

JF - Australian Journal of Physics

ER -

Time-dependent Quantum Waveguide Theory: A Study of Nano Ring Structures

Abstract

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