A novel device now enables scientists to easily adjust the twist between layers of ultra-thin materials, promising ...

In recent years scientists have discovered that the optical, mechanical and electronic properties of the bilayer structures can be fundamentally altered by twisting their crystal lattices against each ...

Department of Physics, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, United States Department of Physics and Astronomy, University of Pittsburgh, Pittsburgh, Pennsylvania 15260, United ...

The team’s results focused on a twisted bilayer of NiI₂ which has a strong, tunable magnetoelectric coupling. This allows external electric fields to precisely control the material’s magnetic phases, ...

Optical reflectivity measurements of Bi2212 have shown that it exhibits strong optical anisotropy. However, this has not been studied through optical transmittance measurements, which can offer ...

The groundbreaking discovery of the new vortex electric field in the twisted bilayer has also created a 2D quasicrystal, potentially enhancing future electronic, magnetic and optical devices.

are known to arise when graphene atomic layers are stacked and twisted with precision to produce "ABC stacking domains." Historically, achieving ABC stacking domains required exfoliating graphene ...

The groundbreaking discovery of the new vortex electric field in the twisted bilayer has also created a 2D quasicrystal, potentially enhancing future electronic, magnetic and optical devices.

The groundbreaking discovery of the new vortex electric field in the twisted bilayer has also created a 2D quasicrystal, potentially enhancing future electronic, magnetic and optical devices.

The novel discovery of a new vortex electric field in the twisted bilayer has also led to the formation of a 2D quasicrystal, which could improve future electronic, magnetic, and optical devices.