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Solar Azo-Switches for Effective E→Z Photoisomerization by Sunlight

Natural photoactive systems have evolved to harness broad-spectrum light from solar radiation for critical functions such as light perception and photosynthetic energy conversion. Molecular photoswitches, which undergo structural changes upon light absorption, are artificial photoactive tools widely...

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Published in:	Angewandte Chemie International Edition 2024-07, Vol.63 (31), p.e202404528
Main Authors:	Zhang, Zhao-Yang, Dong, Dongfang, Bösking, Tom, Dang, Tongtong, Liu, Chunhao, Sun, Wenjin, Xie, Mingchen, Hecht, Stefan, Li, Tao
Format:	Article
Language:	English
Subjects:	Absorption Electromagnetic absorption Energy conversion Energy harvesting Energy technology Isomerization Isomers Light Solar energy Solar energy conversion Solar radiation Sunlight Switches Ultraviolet spectra Visible spectrum
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container_title	Angewandte Chemie International Edition
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creator	Zhang, Zhao-Yang Dong, Dongfang Bösking, Tom Dang, Tongtong Liu, Chunhao Sun, Wenjin Xie, Mingchen Hecht, Stefan Li, Tao
description	Natural photoactive systems have evolved to harness broad-spectrum light from solar radiation for critical functions such as light perception and photosynthetic energy conversion. Molecular photoswitches, which undergo structural changes upon light absorption, are artificial photoactive tools widely used for developing photoresponsive systems and converting light energy. However, photoswitches generally need to be activated by light of specific narrow wavelength ranges for effective photoconversion, which limits their ability to directly work under sunlight and to efficiently harvest solar energy. Here, focusing on azo-switches-the most extensively studied photoswitches, we demonstrate effective solar E→Z photoisomerization with photoconversions exceeding 80 % under unfiltered sunlight. These sunlight-driven azo-switches are developed by rendering the absorption of E isomers overwhelmingly stronger than that of Z isomers across a broad ultraviolet to visible spectrum. This unusual type of spectral profile is realized by a simple yet highly adjustable molecular design strategy, enabling the fine-tuning of spectral window that extends light absorption beyond 600 nm. Notably, back-photoconversion can be achieved without impairing the forward solar isomerization, resulting in unique light-reversible solar switches. Such exceptional solar chemistry of photoswitches provides unprecedented opportunities for developing sustainable light-driven systems and efficient solar energy technologies.
doi_str_mv	10.1002/anie.202404528
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This unusual type of spectral profile is realized by a simple yet highly adjustable molecular design strategy, enabling the fine-tuning of spectral window that extends light absorption beyond 600 nm. Notably, back-photoconversion can be achieved without impairing the forward solar isomerization, resulting in unique light-reversible solar switches. 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subjects	Absorption Electromagnetic absorption Energy conversion Energy harvesting Energy technology Isomerization Isomers Light Solar energy Solar energy conversion Solar radiation Sunlight Switches Ultraviolet spectra Visible spectrum
title	Solar Azo-Switches for Effective E→Z Photoisomerization by Sunlight
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