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Main Authors: Zhang, Chunmei, Zhou, Jian
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.06977
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author Zhang, Chunmei
Zhou, Jian
author_facet Zhang, Chunmei
Zhou, Jian
contents The bulk photovoltaic (BPV) effect that converts light into electric current is highly sensitive to the system symmetry and its electronic Bloch wavefunction. To create a sizable net electric current, it is necessary to break the centrosymmetry P in its host material. While prior studies mainly focus on P-broken nonmagnetic (time reversal T-reserved) and collinear antiferromagnetic PT systems, here we adopt magnetic group theory to scrutinize how helical spin polarization breaks P that is otherwise kept in its crystalline geometry. Such spin helix widely exists in intrinsic multiferroics and magnon excitation in collinear magnets. We demonstrate that magnetic symmetries are determined by spin spiral configurations, helical propagation wavevectors, magnetic chirality, and spin winding angles at the home site, offering effective and versatile manipulation of BPV generation in helimagnets. This is illustrated by tight-binding model calculations. Furthermore, we apply our theory to monolayer NiI2, a realistic showcase for helimagnetic material. Our first-principles calculations show that it could host observable direction-dependent BPV current, which could serve as a photoelectric probe to track the subtle magnetic configurations and potential multiferroic nature. This work reveals the fundamental mechanism of the interplay between spin spiral order and nonlinear optics process.
format Preprint
id arxiv_https___arxiv_org_abs_2312_06977
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Bulk Photovoltaic Effects in Helimagnets
Zhang, Chunmei
Zhou, Jian
Materials Science
The bulk photovoltaic (BPV) effect that converts light into electric current is highly sensitive to the system symmetry and its electronic Bloch wavefunction. To create a sizable net electric current, it is necessary to break the centrosymmetry P in its host material. While prior studies mainly focus on P-broken nonmagnetic (time reversal T-reserved) and collinear antiferromagnetic PT systems, here we adopt magnetic group theory to scrutinize how helical spin polarization breaks P that is otherwise kept in its crystalline geometry. Such spin helix widely exists in intrinsic multiferroics and magnon excitation in collinear magnets. We demonstrate that magnetic symmetries are determined by spin spiral configurations, helical propagation wavevectors, magnetic chirality, and spin winding angles at the home site, offering effective and versatile manipulation of BPV generation in helimagnets. This is illustrated by tight-binding model calculations. Furthermore, we apply our theory to monolayer NiI2, a realistic showcase for helimagnetic material. Our first-principles calculations show that it could host observable direction-dependent BPV current, which could serve as a photoelectric probe to track the subtle magnetic configurations and potential multiferroic nature. This work reveals the fundamental mechanism of the interplay between spin spiral order and nonlinear optics process.
title Bulk Photovoltaic Effects in Helimagnets
topic Materials Science
url https://arxiv.org/abs/2312.06977