Polymeric carbon nitride (PCN), also called melon, is
a well-studied
nonmetal catalyst in the field of photocatalysis, while the nature
of charge transport in PCN has not been thoroughly unveiled at the
microscopic level. In this work, we have combined density functional
theory (DFT) and nonadiabatic dynamics (NAMD) simulations to investigate
the effect of interlayer interactions on the dynamic properties of
photogenerated carriers of melon. Overall, the interlayer π–π
interaction has a greater effect on hot electrons than on holes, which
accelerates the relaxation of electrons in bulk melon. In both monolayer
and bulk melon, electrons and holes have the same antibonding π
bond characteristics, which drives the separation of charges. However,
due to the strong π–π stacking, carriers in bulk
melon can transfer and separate between layers, causing the much longer
nonradiative recombination of charge carriers in bulk than that in
monolayer, which makes melon have a long carrier lifetime and exhibit
photoelectric performance similar to that of inorganic semiconductors