Asymptotic and numerical study of electron flow spin polarization in 2D waveguides of variable cross-section in the presence of magnetic field

L. Baskin, M. Kabardov, P. Neittaanmäki, O. Sarafanov

Результат исследований: Научные публикации в периодических изданияхстатья

3 Цитирования (Scopus)

Выдержка

We consider an infinite two-dimensional waveguide that, far from the coordinate origin, coincides with a strip. The waveguide has two narrows of diameter ε. The narrows play the role of effective potential barriers for the longitudinal electron motion. The part of the waveguide between the narrows becomes a 'resonator', and there can arise conditions for electron resonant tunneling. A magnetic field in the resonator can change the basic characteristics of this phenomenon. In the presence of a magnetic field, the tunneling phenomenon is feasible for producing spin-polarized electron flows consisting of electrons with spins of the same direction. We assume that the whole domain occupied by a magnetic field is in the resonator. An electron wave function satisfies the Pauli equation in the waveguide and vanishes at its boundary. Taking ε as a small parameter, we derive asymptotics for the probability T(E) of an electron with energy E to pass through the resonator, for the 'resonant energy' Eres, where T(E) takes
Язык оригиналаанглийский
Страницы (с-по)1072-1092
ЖурналMathematical Methods in the Applied Sciences
Том37
Номер выпуска7
DOI
СостояниеОпубликовано - 2014

Отпечаток

Spin Polarization
Spin polarization
Waveguide
Numerical Study
Waveguides
Cross section
Magnetic Field
Electron
Magnetic fields
Resonator
Electrons
Resonators
Resonant tunneling
Effective Potential
Wave functions
Energy
Small Parameter
Wave Function
Strip
Vanish

Цитировать

@article{10ad38bc97b948f5b2d3c5cc4926b1ae,
title = "Asymptotic and numerical study of electron flow spin polarization in 2D waveguides of variable cross-section in the presence of magnetic field",
abstract = "We consider an infinite two-dimensional waveguide that, far from the coordinate origin, coincides with a strip. The waveguide has two narrows of diameter ε. The narrows play the role of effective potential barriers for the longitudinal electron motion. The part of the waveguide between the narrows becomes a 'resonator', and there can arise conditions for electron resonant tunneling. A magnetic field in the resonator can change the basic characteristics of this phenomenon. In the presence of a magnetic field, the tunneling phenomenon is feasible for producing spin-polarized electron flows consisting of electrons with spins of the same direction. We assume that the whole domain occupied by a magnetic field is in the resonator. An electron wave function satisfies the Pauli equation in the waveguide and vanishes at its boundary. Taking ε as a small parameter, we derive asymptotics for the probability T(E) of an electron with energy E to pass through the resonator, for the 'resonant energy' Eres, where T(E) takes",
author = "L. Baskin and M. Kabardov and P. Neittaanm{\"a}ki and O. Sarafanov",
year = "2014",
doi = "10.1002/mma.2889",
language = "English",
volume = "37",
pages = "1072--1092",
journal = "Mathematical Methods in the Applied Sciences",
issn = "0170-4214",
publisher = "Wiley-Blackwell",
number = "7",

}

Asymptotic and numerical study of electron flow spin polarization in 2D waveguides of variable cross-section in the presence of magnetic field. / Baskin, L.; Kabardov, M.; Neittaanmäki, P.; Sarafanov, O.

В: Mathematical Methods in the Applied Sciences, Том 37, № 7, 2014, стр. 1072-1092.

Результат исследований: Научные публикации в периодических изданияхстатья

TY - JOUR

T1 - Asymptotic and numerical study of electron flow spin polarization in 2D waveguides of variable cross-section in the presence of magnetic field

AU - Baskin, L.

AU - Kabardov, M.

AU - Neittaanmäki, P.

AU - Sarafanov, O.

PY - 2014

Y1 - 2014

N2 - We consider an infinite two-dimensional waveguide that, far from the coordinate origin, coincides with a strip. The waveguide has two narrows of diameter ε. The narrows play the role of effective potential barriers for the longitudinal electron motion. The part of the waveguide between the narrows becomes a 'resonator', and there can arise conditions for electron resonant tunneling. A magnetic field in the resonator can change the basic characteristics of this phenomenon. In the presence of a magnetic field, the tunneling phenomenon is feasible for producing spin-polarized electron flows consisting of electrons with spins of the same direction. We assume that the whole domain occupied by a magnetic field is in the resonator. An electron wave function satisfies the Pauli equation in the waveguide and vanishes at its boundary. Taking ε as a small parameter, we derive asymptotics for the probability T(E) of an electron with energy E to pass through the resonator, for the 'resonant energy' Eres, where T(E) takes

AB - We consider an infinite two-dimensional waveguide that, far from the coordinate origin, coincides with a strip. The waveguide has two narrows of diameter ε. The narrows play the role of effective potential barriers for the longitudinal electron motion. The part of the waveguide between the narrows becomes a 'resonator', and there can arise conditions for electron resonant tunneling. A magnetic field in the resonator can change the basic characteristics of this phenomenon. In the presence of a magnetic field, the tunneling phenomenon is feasible for producing spin-polarized electron flows consisting of electrons with spins of the same direction. We assume that the whole domain occupied by a magnetic field is in the resonator. An electron wave function satisfies the Pauli equation in the waveguide and vanishes at its boundary. Taking ε as a small parameter, we derive asymptotics for the probability T(E) of an electron with energy E to pass through the resonator, for the 'resonant energy' Eres, where T(E) takes

U2 - 10.1002/mma.2889

DO - 10.1002/mma.2889

M3 - Article

VL - 37

SP - 1072

EP - 1092

JO - Mathematical Methods in the Applied Sciences

JF - Mathematical Methods in the Applied Sciences

SN - 0170-4214

IS - 7

ER -