posted on 2024-05-02, 07:31authored byShuo Hou, Huawei Xie, Fang-Xing Xiao
Wholly distinct from conjugated polymers which are featured
by
generic charge transfer capability stemming from a conjugated molecular
structure, solid nonconjugated polymers mediated charge transport
has long been deemed as theoretically impossible because of the deficiency
of π electrons along the molecular skeleton, thereby retarding
their widespread applications in solar energy conversion. Herein,
we first conceptually unveil that intact encapsulation of metal oxides
(e.g., TiO2, WO3, Fe2O3, and ZnO) with an ultrathin nonconjugated polyelectrolyte of branched
polyethylenimine (BPEI) can unexpectedly accelerate the unidirectional
charge transfer to the active sites and foster the defect generation,
which contributes to the boosted charge separation and prolonged charge
lifetime, ultimately resulting in considerably improved photoelectrochemical
(PEC) water oxidation activities. The interfacial charge transport
origins endowed by BPEI adornment are elucidated, which include acting
as a hole-withdrawing mediator, promoting vacancy generation, and
stimulating the directional charge flow route. We additionally ascertain
that such charge transport characteristics of BPEI are universal.
This work would unlock the charge transfer capability of nonconjugated
polymers for solar water oxidation. The nonconjugated insulating polymer
was utilized as a charge transport mediator for boosting charge migration
and separation over metal oxides toward solar water oxidation.