Abstract:
Two-dimensional semiconductors, owing to their large active surface area and
extraordinary electronic properties, are promising candidates for catalysis in clean
energy applications. In this context, we investigate the optical properties of various
two-dimensional materials such as phosphorene, graphene nitride and transition-
meal dichalcogenides within different first-principles hierarchies.
First, we will discuss the two-dimensional phosphorene and its derivatives.
Since the pristine phosphorene is unstable in air and easily oxidized, we exploit
this chemical instability to our advantage. We argue that the stable derivatives
with N, O and S coverages have the correct band alignment necessary for photo-
catalysis along with high photo-absorption capability. Next, we will discuss the
possibilities in designer van der Waals heterostructures with graphitic carbon ni-
tride g-C 3 N 4 and Janus transition-metal dichalcogenides MoXY. The results are
discussed in the context of photocatalytic water splitting and solar-to-hydrogen
conversion efficiency.
In the end, we will discuss excitonic properties in the two-dimensional materials, which is fundamentally very different from their bulk counterparts due to
much weaker electron screening in the reduced dimension. We describe a tractable
hydrogenic model, where the parameters are calculated from inexpensive and conventional density functional theory. The results, at first, are benchmarked against
relatively more accurate GW-BSE calculations and available experimental results.
Within this methodology, the effects of strain in the lattice and impurities are investigated in phosphorene. Exciton renormalization due to better electron screening is
investigated in thicker samples and heterostructures. Excellent agreement between
the results and the available experimental results indicates the general applicability of
the hydrogenic model to other two-dimensional materials.
Description:
Two-dimensional semiconductors, owing to their large active surface area and
extraordinary electronic properties, are promising candidates for catalysis in clean
energy applications. In this context, we investigate the optical properties of various
two-dimensional materials such as phosphorene, graphene nitride and transition-
meal dichalcogenides within different first-principles hierarchies.