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Bibliographic Details
Main Authors: Singh, Karanpreet, Wilson, Gabe, Stotz, James A. H.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.08125
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author Singh, Karanpreet
Wilson, Gabe
Stotz, James A. H.
author_facet Singh, Karanpreet
Wilson, Gabe
Stotz, James A. H.
contents Through the use of strain and induced piezoelectric fields, surface acoustic waves have been shown to control quantum information processes, such as single photon emission and the coherent transport of electron spins. Regarding the latter, systems using plane surface waves have provided suitable demonstration systems, but to build complexity, more control over the acoustic wave may be required. One method for acoustic control is the use of phononic crystals consisting of periodic arrays of nanofabricated holes on the surface of a device. These inclusions form a metamaterial-like layer with properties different from the normal material to dictate the physics of wave motion. Exploiting these surface properties can lead to acoustic waveguides, which can be designed to control the path of the surface acoustic waves. The design parameters of a new type of phononic crystal waveguide is explored that uses 2-fold elliptical cylinder inclusions to create a slow region that also limits coupling and radiative loss to bulk acoustic modes. Such a waveguide would be the foundational piece in an acoustic circuit that could then mediate complex spin transport geometries.
format Preprint
id arxiv_https___arxiv_org_abs_2411_08125
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimizing Phononic Crystal Waveguides for Acoustically Induced Spin Transport
Singh, Karanpreet
Wilson, Gabe
Stotz, James A. H.
Applied Physics
Materials Science
Through the use of strain and induced piezoelectric fields, surface acoustic waves have been shown to control quantum information processes, such as single photon emission and the coherent transport of electron spins. Regarding the latter, systems using plane surface waves have provided suitable demonstration systems, but to build complexity, more control over the acoustic wave may be required. One method for acoustic control is the use of phononic crystals consisting of periodic arrays of nanofabricated holes on the surface of a device. These inclusions form a metamaterial-like layer with properties different from the normal material to dictate the physics of wave motion. Exploiting these surface properties can lead to acoustic waveguides, which can be designed to control the path of the surface acoustic waves. The design parameters of a new type of phononic crystal waveguide is explored that uses 2-fold elliptical cylinder inclusions to create a slow region that also limits coupling and radiative loss to bulk acoustic modes. Such a waveguide would be the foundational piece in an acoustic circuit that could then mediate complex spin transport geometries.
title Optimizing Phononic Crystal Waveguides for Acoustically Induced Spin Transport
topic Applied Physics
Materials Science
url https://arxiv.org/abs/2411.08125