Crystalline direction dependence of spin precession angle and its application to complementary spin logic devices

Youn Ho Park; Hyung Jun Kim; Joonyeon Chang; Heon Jin Choi; Hyun Cheol Koo

doi:10.1166/jnn.2015.11143

Crystalline direction dependence of spin precession angle and its application to complementary spin logic devices

Youn Ho Park, Hyung Jun Kim, Joonyeon Chang, Heon Jin Choi, Hyun Cheol Koo

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

Abstract

In a semiconductor channel, spin-orbit interaction is divided into two terms, Rashba and Dresselhaus effects, which are key phenomena for modulating spin precession angles. The direction of Rashba field is always perpendicular to the wavevector but that of Dresselhaus field depends on the crystal orientation. Based on the individual Rashba and Dresselhaus strengths, we calculate spin precession angles for various crystal orientations in an InAs quantum well structure. When the channel length is 1 μm, the precession angle is 550° for the [110] direction and 460° for the [1-10] direction, respectively. Using the two spin transistors with different crystal directions, which play roles of n- and p-type transistors in conventional charge transistors, we propose a complementary logic device.

Original language	English
Pages (from-to)	7518-7521
Number of pages	4
Journal	Journal of Nanoscience and Nanotechnology
Volume	15
Issue number	10
DOIs	https://doi.org/10.1166/jnn.2015.11143
Publication status	Published - 2015 Oct

Bibliographical note

Publisher Copyright:
Copyright © 2015 American Scientific Publishers All rights reserved.

Keywords

Dresselhaus effect
Rashba effect
Spin precession angle
Spin-FET
Spin-orbit interaction

ASJC Scopus subject areas

Bioengineering
General Chemistry
Biomedical Engineering
General Materials Science
Condensed Matter Physics

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10.1166/jnn.2015.11143

Cite this

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title = "Crystalline direction dependence of spin precession angle and its application to complementary spin logic devices",

abstract = "In a semiconductor channel, spin-orbit interaction is divided into two terms, Rashba and Dresselhaus effects, which are key phenomena for modulating spin precession angles. The direction of Rashba field is always perpendicular to the wavevector but that of Dresselhaus field depends on the crystal orientation. Based on the individual Rashba and Dresselhaus strengths, we calculate spin precession angles for various crystal orientations in an InAs quantum well structure. When the channel length is 1 μm, the precession angle is 550° for the [110] direction and 460° for the [1-10] direction, respectively. Using the two spin transistors with different crystal directions, which play roles of n- and p-type transistors in conventional charge transistors, we propose a complementary logic device.",

keywords = "Dresselhaus effect, Rashba effect, Spin precession angle, Spin-FET, Spin-orbit interaction",

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AU - Park, Youn Ho

AU - Kim, Hyung Jun

AU - Chang, Joonyeon

AU - Choi, Heon Jin

AU - Koo, Hyun Cheol

PY - 2015/10

Y1 - 2015/10

N2 - In a semiconductor channel, spin-orbit interaction is divided into two terms, Rashba and Dresselhaus effects, which are key phenomena for modulating spin precession angles. The direction of Rashba field is always perpendicular to the wavevector but that of Dresselhaus field depends on the crystal orientation. Based on the individual Rashba and Dresselhaus strengths, we calculate spin precession angles for various crystal orientations in an InAs quantum well structure. When the channel length is 1 μm, the precession angle is 550° for the [110] direction and 460° for the [1-10] direction, respectively. Using the two spin transistors with different crystal directions, which play roles of n- and p-type transistors in conventional charge transistors, we propose a complementary logic device.

AB - In a semiconductor channel, spin-orbit interaction is divided into two terms, Rashba and Dresselhaus effects, which are key phenomena for modulating spin precession angles. The direction of Rashba field is always perpendicular to the wavevector but that of Dresselhaus field depends on the crystal orientation. Based on the individual Rashba and Dresselhaus strengths, we calculate spin precession angles for various crystal orientations in an InAs quantum well structure. When the channel length is 1 μm, the precession angle is 550° for the [110] direction and 460° for the [1-10] direction, respectively. Using the two spin transistors with different crystal directions, which play roles of n- and p-type transistors in conventional charge transistors, we propose a complementary logic device.

KW - Dresselhaus effect

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KW - Spin precession angle

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Crystalline direction dependence of spin precession angle and its application to complementary spin logic devices

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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