Spin Hall effect of radiofrequency waves in magnetized plasmas

Yichen Fu; I. Y. Dodin; Hong Qin

doi:10.1103/PhysRevE.107.055210

Spin Hall effect of radiofrequency waves in magnetized plasmas

Yichen Fu
, I. Y. Dodin
, Hong Qin

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

6 Scopus citations

Abstract

In inhomogeneous media, electromagnetic-wave rays deviate from the trajectories predicted by the leading-order geometrical optics. This effect, called the spin Hall effect of light, is typically neglected in ray-tracing codes used for modeling waves in plasmas. Here, we demonstrate that the spin Hall effect can be significant for radiofrequency waves in toroidal magnetized plasmas whose parameters are in the ballpark of those used in fusion experiments. For example, an electron-cyclotron wave beam can deviate by as large as 10 wavelengths (∼0.1 m) relative to the lowest-order ray trajectory in the poloidal direction. We calculate this displacement using gauge-invariant ray equations of extended geometrical optics, and we also compare our theoretical predictions with full-wave simulations.

Original language	English (US)
Article number	055210
Journal	Physical Review E
Volume	107
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevE.107.055210
State	Published - May 2023

All Science Journal Classification (ASJC) codes

Statistical and Nonlinear Physics
Statistics and Probability
Condensed Matter Physics

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10.1103/PhysRevE.107.055210

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title = "Spin Hall effect of radiofrequency waves in magnetized plasmas",

abstract = "In inhomogeneous media, electromagnetic-wave rays deviate from the trajectories predicted by the leading-order geometrical optics. This effect, called the spin Hall effect of light, is typically neglected in ray-tracing codes used for modeling waves in plasmas. Here, we demonstrate that the spin Hall effect can be significant for radiofrequency waves in toroidal magnetized plasmas whose parameters are in the ballpark of those used in fusion experiments. For example, an electron-cyclotron wave beam can deviate by as large as 10 wavelengths (∼0.1 m) relative to the lowest-order ray trajectory in the poloidal direction. We calculate this displacement using gauge-invariant ray equations of extended geometrical optics, and we also compare our theoretical predictions with full-wave simulations.",

author = "Yichen Fu and Dodin, \{I. Y.\} and Hong Qin",

note = "Publisher Copyright: {\textcopyright} 2023 American Physical Society.",

year = "2023",

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doi = "10.1103/PhysRevE.107.055210",

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T1 - Spin Hall effect of radiofrequency waves in magnetized plasmas

AU - Fu, Yichen

AU - Dodin, I. Y.

AU - Qin, Hong

PY - 2023/5

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N2 - In inhomogeneous media, electromagnetic-wave rays deviate from the trajectories predicted by the leading-order geometrical optics. This effect, called the spin Hall effect of light, is typically neglected in ray-tracing codes used for modeling waves in plasmas. Here, we demonstrate that the spin Hall effect can be significant for radiofrequency waves in toroidal magnetized plasmas whose parameters are in the ballpark of those used in fusion experiments. For example, an electron-cyclotron wave beam can deviate by as large as 10 wavelengths (∼0.1 m) relative to the lowest-order ray trajectory in the poloidal direction. We calculate this displacement using gauge-invariant ray equations of extended geometrical optics, and we also compare our theoretical predictions with full-wave simulations.

AB - In inhomogeneous media, electromagnetic-wave rays deviate from the trajectories predicted by the leading-order geometrical optics. This effect, called the spin Hall effect of light, is typically neglected in ray-tracing codes used for modeling waves in plasmas. Here, we demonstrate that the spin Hall effect can be significant for radiofrequency waves in toroidal magnetized plasmas whose parameters are in the ballpark of those used in fusion experiments. For example, an electron-cyclotron wave beam can deviate by as large as 10 wavelengths (∼0.1 m) relative to the lowest-order ray trajectory in the poloidal direction. We calculate this displacement using gauge-invariant ray equations of extended geometrical optics, and we also compare our theoretical predictions with full-wave simulations.

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DO - 10.1103/PhysRevE.107.055210

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VL - 107

JO - Physical Review E

JF - Physical Review E

IS - 5

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ER -

Spin Hall effect of radiofrequency waves in magnetized plasmas

Abstract

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