posted on 2018-01-15, 00:00authored byYujin Ji, Mingye Yang, Haiping Lin, Tingjun Hou, Lu Wang, Youyong Li, Shuit-Tong Lee
The Janus structures
of transition metal dichalcogenides with an
intrinsic dipole have been proposed as efficient photocatalysts for
water splitting, and successfully synthesized recently. However, the
mechanism for their superior photocatalytic activities are not understood.
Here, we systematically investigate the photocatalytic activities
of Janus molybdenum dichalcogenides (MoXY, X/Y = O, S, Se, and Te),
by studying their band gaps, redox energy levels and electrons and
holes separation, by first-principles calculations. The intrinsic
dipoles in the Janus structures cause notable band bending to achieve
favorable band edge positions relative to water redox potentials,
which makes the Janus structures as efficient heterojunction photocatalysts.
Electrons and holes are spatially separated on different surfaces
of the Janus structure due to the internal electric field, which effectively
inhibits the recombination of excitons and ensures photocatalytic
activity with high efficiency.