Two-dimensional (2D) materials, in general, allow the realization of unique quantum phenomena unattainable in the common ...

The synthesis of 2D material polymers represents a groundbreaking approach in materials science, offering a diverse range of applications in various industries. These composite materials combine the ...

Materials just atoms in thickness, known as two-dimensional (2D) materials, are set to revolutionize future technology, including in the electronics industry. However, commercialization of devices ...

Two-dimensional (2D) materials have atomic-level thickness and excellent mechanical and physical properties, with broad application prospects in fields such as semiconductors, flexible devices, and ...

Researchers from the University of Hong Kong studying the structure of electrons in 2D materials have predicted new types of phase transitions that have yet to be seen in experiments Illustration of ...

Raman spectroscopy has been highlighted as a vital tool for characterizing 2D materials-based van der Waal heterostructures. In this article, we explore its applications in analyzing graphene, TMDs ...

Traditional semiconductors such as Si, GaAs, and HgCdTe seem unable to meet the development trend of electronic devices that feature ultra-small volume, light weight, and low power consumption. These ...

Beyond their sparkle, diamonds have hidden talents. They shed heat better than any material, tolerate extreme temperatures ...

Imagine wearable health sensors, smart packaging, flexible displays, or disposable IoT controllers all manufactured like printed newspapers. The same technology could underpin communication circuits, ...

This mode leverages a multi-frequency approach combined with amplification of the electrical signal through the second eigenmode resonance to enable enhanced sensitivity. It achieves 25 nm edge ...