Recent advances, properties, fabrication and opportunities in two-dimensional materials for their potential sustainable applications

Elemental two-dimensional (2D) materials, characterized by unique chemical, physical, and electrical charac-teristics, now offer intriguing energy and catalysis application possibilities. Their 2D thin structure has con-stricting effects due to their large surface-to-volume ratios, good transport features, and fascinating the physicochemical characteristics. Despite the fact, that emerging elemental 2D materials such as graphene, bor-ophene, silicone, black phosphorene, antimonene, tellurene, bismuthene, and arsenene, etc., are receiving sig-nificant attention in electronics and optoelectronic devices, as well as multiple energy storage and conversion systems, due to their remarkable structural, and electronic characteristics. Particularly, 2D materials have large surface areas, elevated theoretical capacities, structural anisotropy, excellent mobility, and tunable bandgaps, which are intriguing prospects for a variety of energy storage and conversion techniques. As main group elements such as silicon and germanium have favored the area of contemporary electronics, their monolayer 2D in-termediates have shown considerable potential for next-generation electronic metals and potentially game-changing features for optoelectronics, energy, and beyond. Such atomically thin materials have expressed interesting characteristics like near-room-temperature topological insulation in bismuthene, exceptionally elevated electron mobilities in phosphorene and silicone, and significant Li-ion storage capacity in borophene. Recent advancements in the synthesis, analysis and use of several developing 2D materials have been noteworthy. We have demonstrated the basic properties, structure, importance of imperfections and function-alization, explanation of various allotropes, general structure-property correlations, categorization of conjugated polymers, and most recent advancements in the synthesis of 2D materials and their application in various sus-tainable diversity. In this view, we highlight the advancement of new elemental 2D materials in terms of syn-thesis techniques, characteristics, synthesis schemes and merit figures in energy production and catalyst purposes. In addition, we contribute our perspective on the problems and possibilities, which we hope will shed light on the enormous prospects of this ever-expanding industry.

Automated summary

Two-dimensional materials have unique chemical, physical, and electrical characteristics, which make them promising for applications in energy and catalysis. They have been widely studied for their remarkable structural and electronic properties, and their large surface area, theoretical capacity, anisotropy, mobility, and tunable bandgaps make them attractive for energy storage and conversion. Recent advancements in the synthesis and analysis of various 2D materials have been noteworthy, and their application in energy production and catalyst purposes is highly significant.