Abstract
Hexagonal boron nitride (h-BN) and semiconducting transition metal dichalcogenides (TMDs) promise greatly improved electrostatic control in future scaled electronic devices. To quantify the prospects of these materials in devices, we calculate the out-of-plane and in-plane dielectric constant from first principles for TMDs in trigonal prismatic and octahedral coordination, as well as for h-BN, with a thickness ranging from monolayer and bilayer to bulk. Both the ionic and electronic contribution to the dielectric response are computed. Our calculations show that the out-of-plane dielectric response for the transition-metal dichalcogenides is dominated by its electronic component and that the dielectric constant increases with increasing chalcogen atomic number. Overall, the out-of-plane dielectric constant of the TMDs and h-BN increases by less than 15% as the number of layers is increased from monolayer to bulk, while the in-plane component remains unchanged. Our computations also reveal that for octahedrally coordinated TMDs the ionic (static) contribution to the dielectric response is very high (4.5 times the electronic contribution) in the in-plane direction. This indicates that semiconducting TMDs in the tetragonal phase will suffer from excessive polar-optical scattering thereby deteriorating their electronic transport properties.
Highlights
The continued miniaturization of silicon-based electronics along with the exfoliation of graphene from graphite has motivated extensive research toward layered two-dimensional (2D) materials.since graphene does not have a band-gap, it is not well suited for digital electronics applications.[1]
We find that the in-plane dielectric constant is larger than the out-of-plane dielectric response for all the 2D materials
We find that the electronic component dominates the dielectric response except for transition metal dichalcogenides (TMDs) in the tetragonal phase where the ionic contribution is dominant in the in-plane direction
Summary
The continued miniaturization of silicon-based electronics along with the exfoliation of graphene from graphite has motivated extensive research toward layered two-dimensional (2D) materials. The versatility of the electronic and optical properties of layered materials (TMDs) and the ability to exfoliate monolayers and few layers has propelled extensive research in the field of TMDs.[12,13,14,15]. Another intriguing 2D material with a manifold of suggested applications is hexagonal boron-nitride (h-BN). We calculate the macroscopic optical and static relative permittivity values for free-standing monolayer, bilayer and bulk TMDs corresponding to the in-plane and out-of-plane direction.
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