A charge density wave (CDW) represents an exotic state in which electrons are arranged in
a long‐range ordered pattern in low‐dimensional materials. Although the understanding of …

The conductive monolayer 1 T TaS 2 is a promising candidate to promote spintronic devices
to the next level. Through first-principle calculations, we demonstrate that the intrinsic spin …

We investigate, using first-principles methods and effective-model simulations, the spin-orbit
coupling proximity effects in a bilayer heterostructure comprising phosphorene and WSe 2 …

Rashba spin-orbit coupling is a quintessential spin interaction appearing in virtually any
electronic heterostructure. Its paradigmatic spin texture in the momentum space forms a …

We analyze the spin–orbit coupling effects in a 3∘-degree twisted bilayer heterostructure
made of graphene and an in-plane ferroelectric SnTe, with the goal of transferring the spin …

We analyze, using first-principles calculations and the method of invariants, the spin-orbit
proximity effects in trilayer heterostructures comprising phosphorene and encapsulating …

Effective control of interlayer interactions is a key element in modifying the properties of van
der Waals heterostructures and the next step toward their practical applications. Focusing on …

Graphene-based van der Waals heterostructures take advantage of tailoring spin-orbit
coupling (SOC) in the graphene layer by proximity effect. At long-wavelength--saddled by …

Materials exhibiting charge density waves are attracting increasing attention owing to their
complex physics and potential for applications. In this paper, we present a computational …

Proximity-induced phenomena in van der Waals heterostructures have emerged as a
platform to tailor the electronic, spin, optical, and topological properties in two-dimensional …