Diamond possesses excellent thermal conductivity and tunable bandgap. Currently, the high‐
pressure, high‐temperature, and chemical vapor deposition methods are the most promising …

Because of its ultrahigh hardness, synthetic diamond has been widely used in advanced
manufacturing and mechanical engineering. As an ultra-wide bandgap semiconductor, on …

Diamonds exhibit a unique combination of numerous excellent physical and chemical
properties, such as the highest hardness, high Young's modulus, wide bandgap, high carrier …

Recent breakthroughs in the synthesis of diamond have led to increased availability at lower
cost. This has spurred R&D into its characterization and application in machine tools, optical …

Diamond is of great importance for scientific and practical applications. It is the hardest
natural material and holds potential applications in mechanics, electronics and photonics …

Diamond, as an ultra-wide bandgap semiconductor, has become a promising candidate for
next-generation microelectronics and optoelectronics due to its numerous advantages over …

Diamonds may not be forever, but research interest in diamond has never ebbed. Owing to
its highly symmetric crystal structure and strong covalent C–C bonds, diamond possesses …

Diamond, as the densest allotrope of carbon, displays a range of exemplary material
properties that are attractive from a device perspective. Despite diamond displaying high …

Diamond is an allotrope of carbon, and in common with other carbon materials, it has many
extraordinary properties including superhardness for cutting materials and a wide bandgap …

Diamond is considered the most promising next-generation semiconductor material due to
its excellent physical characteristics. It has been more than three decades since the …