Activation
of n → π* Transitions in Two-Dimensional
Conjugated Polymers for Visible Light Photocatalysis
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Abstract
In semiconductor-mediated photocatalysis,
the optical property
of semiconductors is a key parameter and closely related to the conversion
efficiency of solar energy. However, endeavors in achieving a wide
spectral response of semiconductors are still limited in impurity
incorporation or using other assistants. Here, we report on a structure-distortion-induced
extension in the optical absorption of conjugated polymer semiconductors
without relying on any extra species, by taking a typical example
of two-dimensional graphitic carbon nitride (g-C<sub>3</sub>N<sub>4</sub>) nanosheets. Experimental and theoretical calculation results
both identified the close relationship between the band structure
and the structural distortion and the amount of the layers, while
keeping in-plane fundamental units intact and the connecting mode
invariable during the peeling process. Photocatalytic activity was
evaluated toward hydrogen evolution over different samples with visible
light. The results showed that distorted g-C<sub>3</sub>N<sub>4</sub> exhibited higher activity and its wavelength-dependence activity
can be extended to 550 nm with desirable H<sub>2</sub> production.
This finding offers a new channel for researchers to design a polymer
with photocatalytic activity under its extending visible spectrum