Quantum confinement effects and structures with broken inversion symmetry distinguish
transition metal halide (TMD) monolayers from their bulk equivalents in several ways, for …

The discovery of two-dimensional (2D) materials has gained worldwide attention owing to
their extraordinary optical, electrical, and mechanical properties. Due to their atomic layer …

In this work, we explored the interfacial two-dimensional (2D) physics and significant
advancements in the application prospects of MoSSe monolayer when it is combined with a …

Atomically thin transition metal dichalcogenides (TMDCs) are attractive materials for future
optoelectronic applications because of their excellent electrical, optical, and quantum (spin …

The next-generation spintronic device demands the gated control of spin transport across
the semiconducting channel through the replacement of the external gate voltage source by …

The search for new two-dimensional (2D) semiconductors with strong spin-orbit coupling,
merging Rashba effect with valley physics, is essential for advancing the emerging fields of …

First principles density functional theory based calculations have been performed to
investigate the strain and temperature induced tunability of the thermoelectric properties of …

Electrical contacts arising at the van der Waals interface between boron pnictide (h-BP, h-
BAs) and graphene monolayers have been systematically investigated using density …

Despite extensive studies on coupled spin and valley physics, occurrence of these
properties is currently limited to transition-metal dichalcogenides (TMDCs) and graphene …

Room‐temperature chiral light sources whose optical helicity can be electrically switched
are one of the most important devices for future optical quantum information processing. The …