Tuning Acceptor Length in Photocatalytic <scp>Donor‐Acceptor</scp> Conjugated Polymers for Efficient <scp>Solar‐to‐Hydrogen</scp> Energy Conversion
Qian Li, Jia Li, Wenrui Wang, Lina Liu, Ziwen Xu, Guanghui Xie, Jinɡjinɡ Li, Jianhua Yao, Wei‐Shi Li
Abstract
Comprehensive Summary The development of conjugated polymer photocatalysts for efficient solar‐to‐hydrogen energy conversion is highly desirable for the sustainability of our society. Although the construction of donor‐acceptor (D‐A) structure in conjugated polymer photocatalysts for solar‐to‐hydrogen energy conversion has been well documented, less attention has been paid on how large D and how large A units combined together could achieve the best performance. Herein, a series of D‐A copolymers P(BDT‐DBTSO x ) ( x = 7, 19, 39, and 79) composed of a benzodithiophene (BDT) donor unit and an oligomeric dibenzo[ b , d ]thiophene sulfone (DBTSO) acceptor segment were synthesized and studied. It was found that the polymer photocatalytic stabilities under full‐arc irradiation improved upon shortening the length of the acceptor segment. Under visible light irradiation and in the presence of 3 wt% Pt cocatalyst, P(BDT‐DBTSO 79 ) displayed the best performance with an optimal hydrogen evolution rate of 119.3 ± 5.8 mmol·g –1 ·h –1 . This is 1.4‐fold as that of DBTSO homopolymer and 22.5‐fold as that of BDT/DBTSO alternative copolymer, highlighting the importance of acceptor length in D‐A structure for achieving high photocatalytic performance.