The large variety of 2D materials and their co-integration in van der Waals heterostructures
enable innovative device engineering. In addition, their atomically thin nature promotes the …

After the first unequivocal demonstration of spin transport in graphene [Tombros et al.,
Nature (London) 448, 571–574 (2007)], surprisingly at room temperature, it was quickly …

The explosive growth of the information era has put forward urgent requirements for
ultrahigh‐speed and extremely efficient computations. In direct contrary to charge‐based …

In recent years, predictive computational modeling has become a cornerstone for the study
of fundamental electronic, optical, and thermal properties in complex forms of condensed …

We report an unconventional quantum spin Hall phase in the monolayer WTe 2, which
exhibits hitherto unknown features in other topological materials. The low symmetry of the …

Establishing ultimate spin current efficiency in graphene over industry-standard substrates
can facilitate research and development exploration of spin current functions and spin …

Realizations of some topological phases in two-dimensional systems rely on the challenge
of jointly incorporating spin-orbit and magnetic exchange interactions. Here, we predict the …

Nonlocal models are ubiquitous in all branches of science and engineering, with a rapidly
expanding range of mathematical and computational applications due to the ability of such …

The spin polarization induced by the spin Hall effect (SHE) in thin films typically points out of
the plane. This is rooted on the specific symmetries of traditionally studied systems, not in a …

Understanding spin physics in graphene is crucial for develo** future two-dimensional
spintronic devices. Recent studies show that efficient spin-to-charge conversions (SCCs) via …