A Novel Strategy to Construct Artificial Light‐Harvesting System Based on Aggregation‐Induced Emission Surfactants for Photocatalysis

A Novel Strategy to Construct Artificial Light‐Harvesting System Based on Aggregation‐Induced Emission Surfactants for Photocatalysis

Herein, a novel strategy to construct artificial light‐harvesting systems (LHSs) based on micelles is proposed. Two efficient artificial LHSs are fabricated in water based on tetraphenylethene (TPE) modified surfactants (TPE‐SAA). TPE‐SAA can self‐assemble into spherical micelles in an aqueous solut...

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Veröffentlicht in:Advanced optical materials 2023-01, Vol.11 (2), p.n/a
Hauptverfasser: Xing, Ling‐Bao, Wang, Ying, Li, Xin‐Long, Han, Ning, Ma, Chao‐Qun, Liu, Hui, Yu, Shengsheng, Wang, Rongzhou, Zhuo, Shuping
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aerobic cross‐dehydrogenative coupling reaction
Agglomeration
Aqueous solutions
artificial light‐harvesting systems
dehalogenation reaction
Dehydrogenation
Energy transfer
Fluorescent dyes
Light emission
Materials science
Micelles
Optics
sequential energy transfer
Surfactants
white light emission
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container_issue 2
container_start_page
container_title Advanced optical materials
container_volume 11
creator Xing, Ling‐Bao
Wang, Ying
Li, Xin‐Long
Han, Ning
Ma, Chao‐Qun
Liu, Hui
Yu, Shengsheng
Wang, Rongzhou
Zhuo, Shuping
description Herein, a novel strategy to construct artificial light‐harvesting systems (LHSs) based on micelles is proposed. Two efficient artificial LHSs are fabricated in water based on tetraphenylethene (TPE) modified surfactants (TPE‐SAA). TPE‐SAA can self‐assemble into spherical micelles in an aqueous solution through noncovalent interactions. Due to the aggregation‐induced emission effect of the TPE unit, TPE‐SAA micelles exhibit strong emission and directly act as donors to achieve the energy transfer process. Firstly, two fluorescent dyes (4,7‐bis(thien‐2‐yl)‐2,1,3‐benzothiadiazole (DBT) and amphoteric sulforhodamine 101 (SR101)), which are localized in the hydrophobic interior and positively charged surface of TPE‐SAA respectively, are chosen as energy acceptors to realize the two‐step sequential energy transfer process with high efficiency. In addition, energy transfer can also take place from TPE‐SAA to SR101, and bright white‐light emission with a CIE coordinate of (0.31, 0.33) can be achieved by adjusting the ratio of donor to acceptor. Furthermore, to utilize the harvested energy, the micelle‐based artificial LHSs are employed to promote the aerobic cross‐dehydrogenative coupling reaction. Moreover, the dehalogenation reaction of α‐bromoacetophenone can also be catalyzed by the TPE‐SAA+DBT+SR101 system in water. A surfactant with a tetraphenylethene unit (TPE‐SAA) is designed and synthesized. TPE‐SAA can self‐assemble into spherical micelles and serve as an energy donor to fabricate artificial light‐harvesting system (LHS). Two efficient artificial LHSs are successfully fabricated in water through the Förster resonance energy transfer process. In addition, these two systems can serve as a photocatalyst to promote the aerobic cross‐dehydrogenative coupling reaction and the dehalogenation reaction in water.
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Furthermore, to utilize the harvested energy, the micelle‐based artificial LHSs are employed to promote the aerobic cross‐dehydrogenative coupling reaction. Moreover, the dehalogenation reaction of α‐bromoacetophenone can also be catalyzed by the TPE‐SAA+DBT+SR101 system in water. A surfactant with a tetraphenylethene unit (TPE‐SAA) is designed and synthesized. TPE‐SAA can self‐assemble into spherical micelles and serve as an energy donor to fabricate artificial light‐harvesting system (LHS). Two efficient artificial LHSs are successfully fabricated in water through the Förster resonance energy transfer process. 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Furthermore, to utilize the harvested energy, the micelle‐based artificial LHSs are employed to promote the aerobic cross‐dehydrogenative coupling reaction. Moreover, the dehalogenation reaction of α‐bromoacetophenone can also be catalyzed by the TPE‐SAA+DBT+SR101 system in water. A surfactant with a tetraphenylethene unit (TPE‐SAA) is designed and synthesized. TPE‐SAA can self‐assemble into spherical micelles and serve as an energy donor to fabricate artificial light‐harvesting system (LHS). Two efficient artificial LHSs are successfully fabricated in water through the Förster resonance energy transfer process. 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Two efficient artificial LHSs are fabricated in water based on tetraphenylethene (TPE) modified surfactants (TPE‐SAA). TPE‐SAA can self‐assemble into spherical micelles in an aqueous solution through noncovalent interactions. Due to the aggregation‐induced emission effect of the TPE unit, TPE‐SAA micelles exhibit strong emission and directly act as donors to achieve the energy transfer process. Firstly, two fluorescent dyes (4,7‐bis(thien‐2‐yl)‐2,1,3‐benzothiadiazole (DBT) and amphoteric sulforhodamine 101 (SR101)), which are localized in the hydrophobic interior and positively charged surface of TPE‐SAA respectively, are chosen as energy acceptors to realize the two‐step sequential energy transfer process with high efficiency. In addition, energy transfer can also take place from TPE‐SAA to SR101, and bright white‐light emission with a CIE coordinate of (0.31, 0.33) can be achieved by adjusting the ratio of donor to acceptor. Furthermore, to utilize the harvested energy, the micelle‐based artificial LHSs are employed to promote the aerobic cross‐dehydrogenative coupling reaction. Moreover, the dehalogenation reaction of α‐bromoacetophenone can also be catalyzed by the TPE‐SAA+DBT+SR101 system in water. A surfactant with a tetraphenylethene unit (TPE‐SAA) is designed and synthesized. TPE‐SAA can self‐assemble into spherical micelles and serve as an energy donor to fabricate artificial light‐harvesting system (LHS). Two efficient artificial LHSs are successfully fabricated in water through the Förster resonance energy transfer process. In addition, these two systems can serve as a photocatalyst to promote the aerobic cross‐dehydrogenative coupling reaction and the dehalogenation reaction in water.</abstract><cop>Weinheim</cop><pub>Wiley Subscription Services, Inc</pub><doi>10.1002/adom.202201710</doi><tpages>7</tpages><orcidid>https://orcid.org/0000-0003-0920-9049</orcidid></addata></record>
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subjects aerobic cross‐dehydrogenative coupling reaction
Agglomeration
Aqueous solutions
artificial light‐harvesting systems
dehalogenation reaction
Dehydrogenation
Energy transfer
Fluorescent dyes
Light emission
Materials science
Micelles
Optics
sequential energy transfer
Surfactants
white light emission
title A Novel Strategy to Construct Artificial Light‐Harvesting System Based on Aggregation‐Induced Emission Surfactants for Photocatalysis
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