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Main Authors: Mahfouzi, Farzad, Stiles, Mark D., Haney, Paul M.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.22486
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author Mahfouzi, Farzad
Stiles, Mark D.
Haney, Paul M.
author_facet Mahfouzi, Farzad
Stiles, Mark D.
Haney, Paul M.
contents We use a combination of density functional theory calculations and optical modeling to establish that the electric field-induced Kerr rotation in metallic thin films has contributions from both non-equilibrium orbital moment accumulation (arising from the orbital Edelstein effect) and a heretofore overlooked surface Pockels effect. The Kerr rotation associated with orbital accumulation has been studied in previous works and is largely due to the dc electric field-induced change of the electron distribution function. In contrast, the surface Pockels effect is largely due to the dc field-induced change to the wave functions. Both of these contributions arise from the dual mirror symmetry breaking from the surface and from the dc applied field. Our calculations show that the resulting Kerr rotation is due to the dc electric field modification of the optical conductivity within a couple of nanometers from the surface, consistent with the dependence on the local mirror symmetry breaking at the surface. For thin films of Pt, our calculations show that the relative contributions of the orbital Edelstein and surface Pockels effects are comparable, and that they have different effects on Kerr rotation of $s$ and $p$ polarized light, $θ_K^s$ and $θ_K^p$. The orbital Edelstein effect yields similar values of $θ_K^s$ and $θ_K^p$, while the surface Pockels effect leads to opposing values of $θ_K^s$ and $θ_K^p$.
format Preprint
id arxiv_https___arxiv_org_abs_2510_22486
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Electric Field-Induced Kerr Rotation on Metallic Surfaces
Mahfouzi, Farzad
Stiles, Mark D.
Haney, Paul M.
Mesoscale and Nanoscale Physics
Other Condensed Matter
Applied Physics
Computational Physics
Optics
We use a combination of density functional theory calculations and optical modeling to establish that the electric field-induced Kerr rotation in metallic thin films has contributions from both non-equilibrium orbital moment accumulation (arising from the orbital Edelstein effect) and a heretofore overlooked surface Pockels effect. The Kerr rotation associated with orbital accumulation has been studied in previous works and is largely due to the dc electric field-induced change of the electron distribution function. In contrast, the surface Pockels effect is largely due to the dc field-induced change to the wave functions. Both of these contributions arise from the dual mirror symmetry breaking from the surface and from the dc applied field. Our calculations show that the resulting Kerr rotation is due to the dc electric field modification of the optical conductivity within a couple of nanometers from the surface, consistent with the dependence on the local mirror symmetry breaking at the surface. For thin films of Pt, our calculations show that the relative contributions of the orbital Edelstein and surface Pockels effects are comparable, and that they have different effects on Kerr rotation of $s$ and $p$ polarized light, $θ_K^s$ and $θ_K^p$. The orbital Edelstein effect yields similar values of $θ_K^s$ and $θ_K^p$, while the surface Pockels effect leads to opposing values of $θ_K^s$ and $θ_K^p$.
title Electric Field-Induced Kerr Rotation on Metallic Surfaces
topic Mesoscale and Nanoscale Physics
Other Condensed Matter
Applied Physics
Computational Physics
Optics
url https://arxiv.org/abs/2510.22486