Transition-metal chalcogenide quantum dots (TMC QDs)
show great
promise in artificial photosynthesis for excellent light-harvesting
capability. Nonetheless, TMC QDs have limitations of ultrafast charge
recombination rate, sluggish carrier migration kinetics, and generic
photocorrosion, retarding their widespread applications. To solve
these obstacles, herein, we demonstrate the stimulation of charge
migration over TMC QDs with the aid of nonconjugated insulating polymer
and graphene (GR) for a versatile photoredox selective organic transformation.
To this end, an ultrathin insulating polymer layer, i.e., poly(allylamine
hydrochloride) (PAH), grafted on the GR framework, is electrostatically
intercalated at the interface of TMCs QDs and the GR framework via
a self-assembly for constructing TMC QDs/PAH/GR three-dimensional
spatially multilayered heterostructures. In this well-defined nanoarchitecture,
TMC QDs function as a light-harvesting antenna, GR as a terminal electron
reservoir, and PAH as an intermediate interfacial charge relay mediator.
We ascertain that the ultrathin PAH interim layer unexpectedly fosters
the photoelectron migration from TMCs QDs to the GR framework in a
tunable fashion, boosting the charge separation of TMCs QDs and resulting
in significantly improved photoactivities toward anaerobic reduction
of aromatic nitro compounds to amino derivatives and oxidation of
alcohols to aldehydes under visible light. Photoredox catalysis mechanisms
of such TMC QDs/PAH/GR photosystems are elucidated, and the active
species in these photoredox organic conversion reactions are comprehensively
determined. Our work would open new frontiers to finely modulate the
charge transport of TMCs QDs via nonconjugated insulating polymers
for solar energy conversion.