Molecular Engineering of Perylene Diimide Polymers with a Robust Built‐in Electric Field for Enhanced Solar‐Driven Water Splitting

Molecular Engineering of Perylene Diimide Polymers with a Robust Built‐in Electric Field for Enhanced Solar‐Driven Water Splitting

The built‐in electric field of the polymer semiconductors could be regulated by the dipole moment of its building blocks, thereby promoting the separation of photogenerated carriers and achieving efficient solar‐driven water splitting. Herein, three perylene diimide (PDI) polymers, namely oPDI, mPDI...

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Published in:Angewandte Chemie International Edition Vol. 63; no. 8; pp. e202318224 - n/a
Main Authors: Chen, Yi‐Jing, Zhang, Jun‐Zheng, Wu, Zhi‐Xing, Qiao, Ying‐Xin, Zheng, Lei, Wondu Dagnaw, Fentahun, Tong, Qing‐Xiao, Jian, Jing‐Xin
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 19-02-2024
Edition:International ed. in English
Subjects:
Diimide
Dipole moments
Electric fields
Energy conversion
Energy harvesting
Energy levels
Irradiation
Perylene Diimide
Phenylenediamine
Photochemistry
Photoelectric effect
Photoelectrochemistry
Polymers
Robustness
Separation
Solar energy
Solar energy conversion
Splitting
Water Splitting
Photoelectrochemistry
Water Splitting
Perylene Diimide
Photochemistry
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Summary:The built‐in electric field of the polymer semiconductors could be regulated by the dipole moment of its building blocks, thereby promoting the separation of photogenerated carriers and achieving efficient solar‐driven water splitting. Herein, three perylene diimide (PDI) polymers, namely oPDI, mPDI and pPDI, are synthesized with different phenylenediamine linkers. Notably, the energy level structure, light‐harvesting efficiency, and photogenerated carrier separation and migration of polymers are regulated by the orientation of PDI unit. Among them, oPDI enables a large dipole moment and robust built‐in electric field, resulting in enhanced solar‐driven water splitting performance. Under simulated sunlight irradiation, oPDI exhibits the highest photocurrent of 115.1 μA cm−2 for photoelectrochemical oxygen evolution, which is 11.5 times that of mPDI, 26.8 times that of pPDI and 104.6 times that of its counterparts PDI monomer at the same conditions. This work provides a strategy for designing polymers by regulating the orientation of structural units to construct efficient solar energy conversion systems. Three perylene diimide (PDI) polymers were designed and synthesized such that the molecular orientation of the PDI units was regulated to create and modulate their built‐in electric fields. Due to the large dipole moment and interfacial electric field, oPDI enables an extraordinary photocurrent density of 115.1 μA ⋅ cm−2, which is 11.5 and 26.8 times that of mPDI and pPDI, respectively.
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ISSN:1433-7851
1521-3773
1521-3773
DOI:10.1002/anie.202318224