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Main Authors: Zhou, Liang, Du, Zongzheng, Wang, Jinhua, Chen, Pingbo, Ye, Bicong, Feng, Tao, Yang, Jiahao, Xiao, Zehao, Yang, Meng, Li, Junxue, Zhang, Wenqing, Lu, Hai-zhou, He, Hongtao
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.16812
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author Zhou, Liang
Du, Zongzheng
Wang, Jinhua
Chen, Pingbo
Ye, Bicong
Feng, Tao
Yang, Jiahao
Xiao, Zehao
Yang, Meng
Li, Junxue
Zhang, Wenqing
Lu, Hai-zhou
He, Hongtao
author_facet Zhou, Liang
Du, Zongzheng
Wang, Jinhua
Chen, Pingbo
Ye, Bicong
Feng, Tao
Yang, Jiahao
Xiao, Zehao
Yang, Meng
Li, Junxue
Zhang, Wenqing
Lu, Hai-zhou
He, Hongtao
contents Although significant advancements have been made in wireless technologies and portable devices, it remains a challenge for high-frequency and nanowatt-level radiofrequency rectification. In this work, we report a pronounced radiofrequency rectification up to 37 GHz in nominally centrosymmetric SrIrO3 epitaxial films, with the minimum detectable power as low as ~300 nanowatts. Strikingly, the SrIrO3 rectifier is highly field-tunable and exhibits a strong in-plane field anisotropy, thus showing a unique advantage in broad-band radiofrequency rectification. The rectification effect can persist up to at least 360 K and shows a sensitive temperature dependence including a sign inversion. By a systematic study of the nonlinear transport properties of SrIrO3, it is further revealed that the radiofrequency rectification originates from the nonlinear Hall effect with the dominant contribution from field-induced Berry curvature dipole. Our work demonstrates the superior performance of the field-tunable SrIrO3 rectifiers, unleashing the great application potential of centrosymmetric materials in harvesting and detecting ambient electromagnetic energy.
format Preprint
id arxiv_https___arxiv_org_abs_2502_16812
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Room-temperature field-tunable radiofrequency rectification in epitaxial SrIrO3 films
Zhou, Liang
Du, Zongzheng
Wang, Jinhua
Chen, Pingbo
Ye, Bicong
Feng, Tao
Yang, Jiahao
Xiao, Zehao
Yang, Meng
Li, Junxue
Zhang, Wenqing
Lu, Hai-zhou
He, Hongtao
Materials Science
Applied Physics
Although significant advancements have been made in wireless technologies and portable devices, it remains a challenge for high-frequency and nanowatt-level radiofrequency rectification. In this work, we report a pronounced radiofrequency rectification up to 37 GHz in nominally centrosymmetric SrIrO3 epitaxial films, with the minimum detectable power as low as ~300 nanowatts. Strikingly, the SrIrO3 rectifier is highly field-tunable and exhibits a strong in-plane field anisotropy, thus showing a unique advantage in broad-band radiofrequency rectification. The rectification effect can persist up to at least 360 K and shows a sensitive temperature dependence including a sign inversion. By a systematic study of the nonlinear transport properties of SrIrO3, it is further revealed that the radiofrequency rectification originates from the nonlinear Hall effect with the dominant contribution from field-induced Berry curvature dipole. Our work demonstrates the superior performance of the field-tunable SrIrO3 rectifiers, unleashing the great application potential of centrosymmetric materials in harvesting and detecting ambient electromagnetic energy.
title Room-temperature field-tunable radiofrequency rectification in epitaxial SrIrO3 films
topic Materials Science
Applied Physics
url https://arxiv.org/abs/2502.16812