Moiré superlattices, the artificial quantum materials, have provided a wide range of
possibilities for the exploration of completely new physics and device architectures. In this …

Light–matter interaction in 2D and topological materials provides a fascinating control knob
for inducing emergent, non-equilibrium properties and achieving new functionalities in the …

Abstract van der Waals materials have greatly expanded our design space of
heterostructures by allowing individual layers to be stacked at non-equilibrium …

Solid-state quantum devices use quantum entanglement for various quantum technologies,
such as quantum computation, encryption, communication and sensing. Solid-state …

Conventional antiferroelectric materials with atomic-scale anti-aligned dipoles undergo a
transition to a ferroelectric (FE) phase under strong electric fields. The moiré superlattice …

The Hall effects comprise one of the oldest but most vital fields in condensed matter physics,
and they persistently inspire new findings, such as quantum Hall effects and topological …

The isolation of the first two-dimensional material, graphene–a monolayer of carbon atoms
arranged in a hexagonal lattice-opened new exciting opportunities in the field of condensed …

Two-dimensional (2D) van der Waals (vdW) materials, featuring relaxed phase-matching
conditions and highly tunable optical nonlinearity, endow them with potential applications in …

Ti-MXene allows a range of possibilities to tune their compositional stoichiometry due to
their electronic and electrochemical properties. Other than conventionally explored Ti …

Van der Waals dielectrics are fundamental materials for condensed matter physics and
advanced electronic applications. Most dielectrics host isotropic structures in crystalline or …