Synergistic Effect of Crown Ether and Main-Chain Engineering for Boosting Hydrogen Evolution of Polymer Photocatalysts in Seawater

Chih Li Chang; Tse Fu Huang; Wei Cheng Lin; Li Yu Ting; Chin Hsuan Shih; Yan Heng Chen; Jia Jen Liu; Yu Tung Lin; Yuang Ting Tseng; Yi Hsiang Wu; Yu En Sun; Mohamed Hammad Elsayed; Chin Wen Chen; Chi Hua Yu; Ho Hsiu Chou

doi:10.1002/aenm.202300986

Synergistic Effect of Crown Ether and Main-Chain Engineering for Boosting Hydrogen Evolution of Polymer Photocatalysts in Seawater

Chih Li Chang, Tse Fu Huang, Wei Cheng Lin, Li Yu Ting, Chin Hsuan Shih, Yan Heng Chen, Jia Jen Liu, Yu Tung Lin, Yuang Ting Tseng, Yi Hsiang Wu, Yu En Sun, Mohamed Hammad Elsayed, Chin Wen Chen^*, Chi Hua Yu^*, Ho Hsiu Chou^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

Photocatalytic hydrogen evolution from natural seawater faces the severe challenges of abundant salts, which adsorb on the active sites and result in undesirable side reactions and photocatalyst poisoning. Herein, a series of main-chain-engineered discontinuously conjugated polymer (DCP) photocatalysts is presented with bifunctional crown ether (CE) structures for hydrogen evolution from seawater. The hydrophilic CE can significantly inhibit the aggregation of DCPs induced by salts. Meanwhile, cyclic CE can effectively adsorb cations to uncover the active sites to increase their interaction with protons, which can increase the hydrogen evolution rates and significantly reduce the efficiency roll-off in natural seawater. Through atomistic studies, the formation of hydrogen bonds with bifunctional CE is elucidated and further analysis of the microscale mechanisms is also conducted using molecular dynamics and ab initio techniques. This work suggests that CE-based polymer has the potential to enhance its ability to produce hydrogen through photocatalysis using seawater.

Original language	English
Article number	2300986
Journal	Advanced Energy Materials
Volume	13
Issue number	29
DOIs	https://doi.org/10.1002/aenm.202300986
State	Published - 4 Aug 2023
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2023 Wiley-VCH GmbH.

Keywords

conjugated polymers
crown ether
hydrogen evolution from seawater
hydrogen evolution reaction
main-chain engineering
sodium-ions capture
visible light-driven water splitting

ASJC Scopus subject areas

Renewable Energy, Sustainability and the Environment
General Materials Science

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1002/aenm.202300986

Cite this

Chang, C. L., Huang, T. F., Lin, W. C., Ting, L. Y., Shih, C. H., Chen, Y. H., Liu, J. J., Lin, Y. T., Tseng, Y. T., Wu, Y. H., Sun, Y. E., Elsayed, M. H., Chen, C. W., Yu, C. H., & Chou, H. H. (2023). Synergistic Effect of Crown Ether and Main-Chain Engineering for Boosting Hydrogen Evolution of Polymer Photocatalysts in Seawater. Advanced Energy Materials, 13(29), Article 2300986. https://doi.org/10.1002/aenm.202300986

@article{b13f5de07e204ed79844b3a9c76fa312,

title = "Synergistic Effect of Crown Ether and Main-Chain Engineering for Boosting Hydrogen Evolution of Polymer Photocatalysts in Seawater",

abstract = "Photocatalytic hydrogen evolution from natural seawater faces the severe challenges of abundant salts, which adsorb on the active sites and result in undesirable side reactions and photocatalyst poisoning. Herein, a series of main-chain-engineered discontinuously conjugated polymer (DCP) photocatalysts is presented with bifunctional crown ether (CE) structures for hydrogen evolution from seawater. The hydrophilic CE can significantly inhibit the aggregation of DCPs induced by salts. Meanwhile, cyclic CE can effectively adsorb cations to uncover the active sites to increase their interaction with protons, which can increase the hydrogen evolution rates and significantly reduce the efficiency roll-off in natural seawater. Through atomistic studies, the formation of hydrogen bonds with bifunctional CE is elucidated and further analysis of the microscale mechanisms is also conducted using molecular dynamics and ab initio techniques. This work suggests that CE-based polymer has the potential to enhance its ability to produce hydrogen through photocatalysis using seawater.",

keywords = "conjugated polymers, crown ether, hydrogen evolution from seawater, hydrogen evolution reaction, main-chain engineering, sodium-ions capture, visible light-driven water splitting",

author = "Chang, {Chih Li} and Huang, {Tse Fu} and Lin, {Wei Cheng} and Ting, {Li Yu} and Shih, {Chin Hsuan} and Chen, {Yan Heng} and Liu, {Jia Jen} and Lin, {Yu Tung} and Tseng, {Yuang Ting} and Wu, {Yi Hsiang} and Sun, {Yu En} and Elsayed, {Mohamed Hammad} and Chen, {Chin Wen} and Yu, {Chi Hua} and Chou, {Ho Hsiu}",

note = "Publisher Copyright: {\textcopyright} 2023 Wiley-VCH GmbH.",

year = "2023",

month = aug,

day = "4",

doi = "10.1002/aenm.202300986",

language = "English",

volume = "13",

journal = "Advanced Energy Materials",

issn = "1614-6832",

publisher = "John Wiley and Sons Inc.",

number = "29",

}

Chang, CL, Huang, TF, Lin, WC, Ting, LY, Shih, CH, Chen, YH, Liu, JJ, Lin, YT, Tseng, YT, Wu, YH, Sun, YE, Elsayed, MH, Chen, CW, Yu, CH & Chou, HH 2023, 'Synergistic Effect of Crown Ether and Main-Chain Engineering for Boosting Hydrogen Evolution of Polymer Photocatalysts in Seawater', Advanced Energy Materials, vol. 13, no. 29, 2300986. https://doi.org/10.1002/aenm.202300986

TY - JOUR

T1 - Synergistic Effect of Crown Ether and Main-Chain Engineering for Boosting Hydrogen Evolution of Polymer Photocatalysts in Seawater

AU - Chang, Chih Li

AU - Huang, Tse Fu

AU - Lin, Wei Cheng

AU - Ting, Li Yu

AU - Shih, Chin Hsuan

AU - Chen, Yan Heng

AU - Liu, Jia Jen

AU - Lin, Yu Tung

AU - Tseng, Yuang Ting

AU - Wu, Yi Hsiang

AU - Sun, Yu En

AU - Elsayed, Mohamed Hammad

AU - Chen, Chin Wen

AU - Yu, Chi Hua

AU - Chou, Ho Hsiu

PY - 2023/8/4

Y1 - 2023/8/4

N2 - Photocatalytic hydrogen evolution from natural seawater faces the severe challenges of abundant salts, which adsorb on the active sites and result in undesirable side reactions and photocatalyst poisoning. Herein, a series of main-chain-engineered discontinuously conjugated polymer (DCP) photocatalysts is presented with bifunctional crown ether (CE) structures for hydrogen evolution from seawater. The hydrophilic CE can significantly inhibit the aggregation of DCPs induced by salts. Meanwhile, cyclic CE can effectively adsorb cations to uncover the active sites to increase their interaction with protons, which can increase the hydrogen evolution rates and significantly reduce the efficiency roll-off in natural seawater. Through atomistic studies, the formation of hydrogen bonds with bifunctional CE is elucidated and further analysis of the microscale mechanisms is also conducted using molecular dynamics and ab initio techniques. This work suggests that CE-based polymer has the potential to enhance its ability to produce hydrogen through photocatalysis using seawater.

AB - Photocatalytic hydrogen evolution from natural seawater faces the severe challenges of abundant salts, which adsorb on the active sites and result in undesirable side reactions and photocatalyst poisoning. Herein, a series of main-chain-engineered discontinuously conjugated polymer (DCP) photocatalysts is presented with bifunctional crown ether (CE) structures for hydrogen evolution from seawater. The hydrophilic CE can significantly inhibit the aggregation of DCPs induced by salts. Meanwhile, cyclic CE can effectively adsorb cations to uncover the active sites to increase their interaction with protons, which can increase the hydrogen evolution rates and significantly reduce the efficiency roll-off in natural seawater. Through atomistic studies, the formation of hydrogen bonds with bifunctional CE is elucidated and further analysis of the microscale mechanisms is also conducted using molecular dynamics and ab initio techniques. This work suggests that CE-based polymer has the potential to enhance its ability to produce hydrogen through photocatalysis using seawater.

KW - conjugated polymers

KW - crown ether

KW - hydrogen evolution from seawater

KW - hydrogen evolution reaction

KW - main-chain engineering

KW - sodium-ions capture

KW - visible light-driven water splitting

UR - http://www.scopus.com/inward/record.url?scp=85161099602&partnerID=8YFLogxK

U2 - 10.1002/aenm.202300986

DO - 10.1002/aenm.202300986

M3 - Article

AN - SCOPUS:85161099602

SN - 1614-6832

VL - 13

JO - Advanced Energy Materials

JF - Advanced Energy Materials

IS - 29

M1 - 2300986

ER -

Synergistic Effect of Crown Ether and Main-Chain Engineering for Boosting Hydrogen Evolution of Polymer Photocatalysts in Seawater

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

Access to Document

Fingerprint

Cite this