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Main Authors: Jiang, Xuanyuan, Wang, Xiao, Buragohain, Pratyush, Clark, Andy, Lu, Haidong, Poddar, Shashi, Yu, Le, DiChiara, Anthony D, Gruverman, Alexei, Cheng, Xuemei, Xu, Xiaoshan
Format: Preprint
Published: 2021
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Online Access:https://arxiv.org/abs/2105.02628
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author Jiang, Xuanyuan
Wang, Xiao
Buragohain, Pratyush
Clark, Andy
Lu, Haidong
Poddar, Shashi
Yu, Le
DiChiara, Anthony D
Gruverman, Alexei
Cheng, Xuemei
Xu, Xiaoshan
author_facet Jiang, Xuanyuan
Wang, Xiao
Buragohain, Pratyush
Clark, Andy
Lu, Haidong
Poddar, Shashi
Yu, Le
DiChiara, Anthony D
Gruverman, Alexei
Cheng, Xuemei
Xu, Xiaoshan
contents Photoexcitation is well-known to trigger electronic metastable states and lead to phenomena like long-lived photoluminescence and photoconductivity. In contrast, persistent photo-response due to ionic metastable states is rare. In this work, we report persistent structural and ferroelectric photo-responses due to proton metastable states via a nuclear quantum mechanism in ferroelectric croconic acid, in which the proton-transfer origin of ferroelectricity is important for the ionic metastable states. We show that, after photoexcitation, the changes of structural and ferroelectric properties relax in about 1000 s, while the photoconductivity decays within 1 s, indicating the dominant ionic origin of the responses. The photogenerated internal bias field that survives polarization switching process suggests another proton transfer route and metastable state, in addition to the metastable states resulting from proton transfer along the hydrogen bonds proposed previously. Analysis based on Frank Condon principle reveals the quantum mechanical nature of the proton-transfer process both within the hydrogen bonds and out of the hydrogen bonds, where small mass of proton and significant change of potential landscape due to the excited electronic states are the key. The demonstration of persistent photo-responses due to the proton metastable states unveils a nuclear quantum mechanism for photo-tunability of materials, which is expected to impact many material properties sensitive to ionic positions.
format Preprint
id arxiv_https___arxiv_org_abs_2105_02628
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Persistent Ionic Photo-responses and Frank-Condon Mechanism in Proton-transfer Ferroelectrics
Jiang, Xuanyuan
Wang, Xiao
Buragohain, Pratyush
Clark, Andy
Lu, Haidong
Poddar, Shashi
Yu, Le
DiChiara, Anthony D
Gruverman, Alexei
Cheng, Xuemei
Xu, Xiaoshan
Materials Science
Photoexcitation is well-known to trigger electronic metastable states and lead to phenomena like long-lived photoluminescence and photoconductivity. In contrast, persistent photo-response due to ionic metastable states is rare. In this work, we report persistent structural and ferroelectric photo-responses due to proton metastable states via a nuclear quantum mechanism in ferroelectric croconic acid, in which the proton-transfer origin of ferroelectricity is important for the ionic metastable states. We show that, after photoexcitation, the changes of structural and ferroelectric properties relax in about 1000 s, while the photoconductivity decays within 1 s, indicating the dominant ionic origin of the responses. The photogenerated internal bias field that survives polarization switching process suggests another proton transfer route and metastable state, in addition to the metastable states resulting from proton transfer along the hydrogen bonds proposed previously. Analysis based on Frank Condon principle reveals the quantum mechanical nature of the proton-transfer process both within the hydrogen bonds and out of the hydrogen bonds, where small mass of proton and significant change of potential landscape due to the excited electronic states are the key. The demonstration of persistent photo-responses due to the proton metastable states unveils a nuclear quantum mechanism for photo-tunability of materials, which is expected to impact many material properties sensitive to ionic positions.
title Persistent Ionic Photo-responses and Frank-Condon Mechanism in Proton-transfer Ferroelectrics
topic Materials Science
url https://arxiv.org/abs/2105.02628