Chiral microwave nonreciprocity demonstrated via Rayleigh and Sezawa modes supported in an Al0.58Sc0.42 N/4H-SiC platform

A. R. Will-Cole; Xingyu Du; Bin Luo; Valeria Lauter; Alexander Grutter; Lisa Hackett; Michael Miller; Yuanchen Deng; Brandon Smith; Olivia Pitcl; Nian X. Sun; Roy H. Olsson; Matt Eichenfield

doi:10.1103/PhysRevApplied.23.034058

Chiral microwave nonreciprocity demonstrated via Rayleigh and Sezawa modes supported in an Al_0.58Sc_0.42 N/4H-SiC platform

A. R. Will-Cole
, Xingyu Du
, Bin Luo
, Valeria Lauter
, Alexander Grutter
, Lisa Hackett
, Michael Miller
, Yuanchen Deng
, Brandon Smith
, Olivia Pitcl
, Nian X. Sun
, Roy H. Olsson
, Matt Eichenfield

Reflectometry

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

2 Scopus citations

Abstract

Chirality plays a crucial role in the helicity mismatch between surface acoustic waves and magnetic spin waves, leading to nonreciprocal transmission of acoustic power for coupled magnetoacoustic modes. Acoustic modes with both longitudinal and shear strain exhibit elliptical particle displacements, making them chiral, and different acoustic modes can exhibit different helicities of this elliptical particle displacement. Here, we study chiral acoustic modes with different helicities supported on the same piezoelectric platform and their interaction with magnetic spin waves. Our study demonstrates that the nonreciprocal transmission of acoustic power is driven by the helicity mismatch effect and, specifically, that the handedness of the nonreciprocity is based on whether the surface acoustic wave has retrograde (Rayleigh mode) or prograde (Sezawa mode) elliptical particle displacement with respect to the propagation direction. We found the transmission nonreciprocity to be significant, with 7.3 dB/mm for the retrograde particle displacement (Rayleigh mode at 2.358 GHz) and 3.3 dB/mm for prograde particle displacement (Sezawa mode at 3.112 GHz). This work highlights that piezoelectric platforms can be engineered to support acoustic modes with opposite helicities to enable frequency-selective nonreciprocal radiofrequency and microwave components, such as isolators and circulators, through coupled acoustic spin wave interactions.

Original language	English
Article number	034058
Journal	Physical Review Applied
Volume	23
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevApplied.23.034058
State	Published - Mar 2025

Funding

This project was funded in part by the DARPA Young Faculty Award program. A portion of this research used resources at Sandia National Laboratories. Sandia National Laboratories is a multimission laboratory managed and operated by National Technology & Engineering Solutions of Sandia, LLC, a wholly owned subsidiary of Honeywell International Inc., for the U.S. Department of Energy’s National Nuclear Security Administration under contract DE-NA0003525. This work was performed, in part, at the Center for Integrated Nanotechnologies, an Office of Science User Facility operated for the U.S. Department of Energy (DOE) Office of Science.

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10.1103/PhysRevApplied.23.034058

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Will-Cole, A. R., Du, X., Luo, B., Lauter, V., Grutter, A., Hackett, L., Miller, M., Deng, Y., Smith, B., Pitcl, O., Sun, N. X., Olsson, R. H., & Eichenfield, M. (2025). Chiral microwave nonreciprocity demonstrated via Rayleigh and Sezawa modes supported in an Al_0.58Sc_0.42 N/4H-SiC platform. Physical Review Applied, 23(3), Article 034058. https://doi.org/10.1103/PhysRevApplied.23.034058

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title = "Chiral microwave nonreciprocity demonstrated via Rayleigh and Sezawa modes supported in an Al0.58Sc0.42 N/4H-SiC platform",

abstract = "Chirality plays a crucial role in the helicity mismatch between surface acoustic waves and magnetic spin waves, leading to nonreciprocal transmission of acoustic power for coupled magnetoacoustic modes. Acoustic modes with both longitudinal and shear strain exhibit elliptical particle displacements, making them chiral, and different acoustic modes can exhibit different helicities of this elliptical particle displacement. Here, we study chiral acoustic modes with different helicities supported on the same piezoelectric platform and their interaction with magnetic spin waves. Our study demonstrates that the nonreciprocal transmission of acoustic power is driven by the helicity mismatch effect and, specifically, that the handedness of the nonreciprocity is based on whether the surface acoustic wave has retrograde (Rayleigh mode) or prograde (Sezawa mode) elliptical particle displacement with respect to the propagation direction. We found the transmission nonreciprocity to be significant, with 7.3 dB/mm for the retrograde particle displacement (Rayleigh mode at 2.358 GHz) and 3.3 dB/mm for prograde particle displacement (Sezawa mode at 3.112 GHz). This work highlights that piezoelectric platforms can be engineered to support acoustic modes with opposite helicities to enable frequency-selective nonreciprocal radiofrequency and microwave components, such as isolators and circulators, through coupled acoustic spin wave interactions.",

author = "Will-Cole, \{A. R.\} and Xingyu Du and Bin Luo and Valeria Lauter and Alexander Grutter and Lisa Hackett and Michael Miller and Yuanchen Deng and Brandon Smith and Olivia Pitcl and Sun, \{Nian X.\} and Olsson, \{Roy H.\} and Matt Eichenfield",

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doi = "10.1103/PhysRevApplied.23.034058",

language = "English",

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Will-Cole, AR, Du, X, Luo, B, Lauter, V, Grutter, A, Hackett, L, Miller, M, Deng, Y, Smith, B, Pitcl, O, Sun, NX, Olsson, RH & Eichenfield, M 2025, 'Chiral microwave nonreciprocity demonstrated via Rayleigh and Sezawa modes supported in an Al_0.58Sc_0.42 N/4H-SiC platform', Physical Review Applied, vol. 23, no. 3, 034058. https://doi.org/10.1103/PhysRevApplied.23.034058

TY - JOUR

T1 - Chiral microwave nonreciprocity demonstrated via Rayleigh and Sezawa modes supported in an Al0.58Sc0.42 N/4H-SiC platform

AU - Will-Cole, A. R.

AU - Du, Xingyu

AU - Luo, Bin

AU - Lauter, Valeria

AU - Grutter, Alexander

AU - Hackett, Lisa

AU - Miller, Michael

AU - Deng, Yuanchen

AU - Smith, Brandon

AU - Pitcl, Olivia

AU - Sun, Nian X.

AU - Olsson, Roy H.

AU - Eichenfield, Matt

PY - 2025/3

Y1 - 2025/3

N2 - Chirality plays a crucial role in the helicity mismatch between surface acoustic waves and magnetic spin waves, leading to nonreciprocal transmission of acoustic power for coupled magnetoacoustic modes. Acoustic modes with both longitudinal and shear strain exhibit elliptical particle displacements, making them chiral, and different acoustic modes can exhibit different helicities of this elliptical particle displacement. Here, we study chiral acoustic modes with different helicities supported on the same piezoelectric platform and their interaction with magnetic spin waves. Our study demonstrates that the nonreciprocal transmission of acoustic power is driven by the helicity mismatch effect and, specifically, that the handedness of the nonreciprocity is based on whether the surface acoustic wave has retrograde (Rayleigh mode) or prograde (Sezawa mode) elliptical particle displacement with respect to the propagation direction. We found the transmission nonreciprocity to be significant, with 7.3 dB/mm for the retrograde particle displacement (Rayleigh mode at 2.358 GHz) and 3.3 dB/mm for prograde particle displacement (Sezawa mode at 3.112 GHz). This work highlights that piezoelectric platforms can be engineered to support acoustic modes with opposite helicities to enable frequency-selective nonreciprocal radiofrequency and microwave components, such as isolators and circulators, through coupled acoustic spin wave interactions.

AB - Chirality plays a crucial role in the helicity mismatch between surface acoustic waves and magnetic spin waves, leading to nonreciprocal transmission of acoustic power for coupled magnetoacoustic modes. Acoustic modes with both longitudinal and shear strain exhibit elliptical particle displacements, making them chiral, and different acoustic modes can exhibit different helicities of this elliptical particle displacement. Here, we study chiral acoustic modes with different helicities supported on the same piezoelectric platform and their interaction with magnetic spin waves. Our study demonstrates that the nonreciprocal transmission of acoustic power is driven by the helicity mismatch effect and, specifically, that the handedness of the nonreciprocity is based on whether the surface acoustic wave has retrograde (Rayleigh mode) or prograde (Sezawa mode) elliptical particle displacement with respect to the propagation direction. We found the transmission nonreciprocity to be significant, with 7.3 dB/mm for the retrograde particle displacement (Rayleigh mode at 2.358 GHz) and 3.3 dB/mm for prograde particle displacement (Sezawa mode at 3.112 GHz). This work highlights that piezoelectric platforms can be engineered to support acoustic modes with opposite helicities to enable frequency-selective nonreciprocal radiofrequency and microwave components, such as isolators and circulators, through coupled acoustic spin wave interactions.

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DO - 10.1103/PhysRevApplied.23.034058

M3 - Article

AN - SCOPUS:105001032959

SN - 2331-7019

VL - 23

JO - Physical Review Applied

JF - Physical Review Applied

IS - 3

M1 - 034058

ER -

Chiral microwave nonreciprocity demonstrated via Rayleigh and Sezawa modes supported in an Al_0.58Sc_0.42 N/4H-SiC platform

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