Anisotropic 2D materials are promising building blocks for future photonic and
optoelectronic devices due to their low structural symmetry and in‐plane optical anisotropy …

The exciton binding energy (Eb) is a key parameter that governs the physics of many
optoelectronic devices. At their best, trustworthy and precise measurements of Eb challenge …

The isolation of graphene and transition metal dichalcongenides has opened a veritable
world to a great number of layered materials which can be exfoliated, manipulated, and …

Advanced microscopy and/or spectroscopy tools play indispensable roles in nanoscience
and nanotechnology research, as they provide rich information about material processes …

Do** usually reduces lattice thermal conductivity because of enhanced phonon-impurity
scattering. Here, we report unexpected do** effects on the lattice thermal conductivity of …

The strong in-plane anisotropy and quasi-1D electronic structures of transition-metal
trichalcogenides (MX3; M= group IV or V transition metal; X= S, Se, or Te) have pronounced …

The discovery of graphene, a single atomic layer of carbon in a hexagonal lattice, has
invigorated enormous research interests in two‐dimensional (2D) layered materials and …

Titanium trisulphide (TiS 3) has been widely used in the field of optoelectronics owing to its
superb optical and electronic characteristics. In this work, a self-powered photodetector …

Low symmetry 2D materials with intrinsic in-plane anisotropic optical properties and high
tunability provide a promising platform to explore and manipulate light–matter interactions …

Abstract Two-dimensional (2D) layered materials exhibit strong light-matter interactions,
remarkable excitonic effects, and ultrafast optical response, making them promising for high …