The exceptional physical properties and unique layered structure of two-dimensional (2D)
materials have made this class of materials great candidates for applications in electronics …

With the rapid development of micro‐electromechanical systems (MEMS), micro/nanoscale
fabrication of 3D metallic structures with complex structures and multifunctions is becoming …

Liquid-phase exfoliation (LPE) is the principal method of producing two-dimensional (2D)
materials such as graphene in large quantities with a good balance between quality and …

This article is to capture some of the important developments in the rapidly growing areas of
laser-based manufacturing and materials processing and also to describe important …

Wearable multimodal sensors could enable the continuous, non‐invasive, precise
monitoring of vital human signals critical for remote health monitoring and telemedicine …

Strain engineering of 2D materials is capable of tuning the electrical and optical properties
of the materials without introducing additional atoms. Here, a method for large-scale ultrafast …

Interfaces are often crucial determinants of the physicochemical properties of a material. As
a result, the rational production and engineering of heterogeneities, and the resulting …

This review explores the growing interest in 2D layered materials, such as graphene, h‐BN,
transition metal dichalcogenides (TMDs), and black phosphorus (BP), with a specific focus …

Mechanical strain, such as stretching, compression, bending, and rotation, significantly
alters the photonic and electronic properties of 2D materials. The laser shock process, which …

The poor light absorption and limited bandgap of monolayer 2D materials limit the overall
performance of optoelectronic devices. In order to overcome these limitations, a method of …