Two‐dimensional materials and synthesis, energy storage, utilization, and conversion applications of two‐dimensional MXene materials

Abstract: Summary Owing to the first‐rate residences of graphene, the research had been achieved on novel two‐dimensional (2D) materials. The MXene is a 2D inorganic compound that consists of transition metal carbides, nitrides, and carbonitrides. Ti₃C₂, the primary 2D‐layered MXene, was reported in 2011. This material that is a layered bulk material analogous to graphite, changed into derived from its 3D phase, is Ti₃AlC₂ MAX. The start of this review through reviewing the structures and morphologies and their fabricat… Show more

“…The heterostructures of 2D materials were also studied for the application of photodetectors. The common example is graphene and MoS 2 heterostructures applied for the photodetector application, and results concluded that the photo gains were more than 10. , …”

“…The common example is graphene and MoS 2 heterostructures applied for the photodetector application, and results concluded that the photo gains were more than 10. 8,146 Short Overview on Synthesis of Heterostructures. There are two main conventional methods to synthesize or construct the 2D-materialbased heterostructures: one is mechanical assembly, and the other is the in situ growth method.…”

“…Moreover, safe operation, cost reduction, freedom from negative ecological impacts, and easy portability make the metal-ion batteries the first choice for energy storage. Recent advancements have enabled the deployment of batteries in a wide range of applications, from small-scale portable electronics to large-scale energy storage systems, electric vehicles, and renewable energy integration. − Despite the remarkable progress in battery technology, significant scientific and engineering challenges remain to be tackled, including the need to improve energy and power density, cycle life and durability, safety, and sustainability. − To meet these challenges, research and development efforts are required to develop new electrode materials (both cathode and anode) and electrolyte to provide higher energy storage capacity and faster charge–discharge rates, and to improve the reliability of battery management systems. − …”

Borophene Potential for Developing Next-Generation Battery Applications: A Comprehensive Review

“…The heterostructures of 2D materials were also studied for the application of photodetectors. The common example is graphene and MoS 2 heterostructures applied for the photodetector application, and results concluded that the photo gains were more than 10. , …”

“…The common example is graphene and MoS 2 heterostructures applied for the photodetector application, and results concluded that the photo gains were more than 10. 8,146 Short Overview on Synthesis of Heterostructures. There are two main conventional methods to synthesize or construct the 2D-materialbased heterostructures: one is mechanical assembly, and the other is the in situ growth method.…”

“…Moreover, safe operation, cost reduction, freedom from negative ecological impacts, and easy portability make the metal-ion batteries the first choice for energy storage. Recent advancements have enabled the deployment of batteries in a wide range of applications, from small-scale portable electronics to large-scale energy storage systems, electric vehicles, and renewable energy integration. − Despite the remarkable progress in battery technology, significant scientific and engineering challenges remain to be tackled, including the need to improve energy and power density, cycle life and durability, safety, and sustainability. − To meet these challenges, research and development efforts are required to develop new electrode materials (both cathode and anode) and electrolyte to provide higher energy storage capacity and faster charge–discharge rates, and to improve the reliability of battery management systems. − …”

Borophene Potential for Developing Next-Generation Battery Applications: A Comprehensive Review

“…Two-dimensional materials have large surface-to-volume ratios and good dispersion in liquid media, giving unique functions. Their applications in separation, 46 electronic engineering, 47 energy and gas storage, 48 light capture and conversion 49 have aroused great interest. Two-dimensional supramolecular organic luminescent assemblies include single-layer metal–organic framework (MOF), 50 covalent organic framework (COF), 51 supramolecular organic framework (SOF), 52 and 2D polyrotaxane.…”

A supramolecular assembly strategy towards organic luminescent materials

“…Compared to the top-down approach, the bottom-up approach offers several advantages, including higher atomic utilization, better control of morphology, and a narrower size distribution [17,18]. The synthesis of TMD QDs using the bottom-up approach has already been described in unmerous reports and does not need to be repeated here [9,[17][18][19][20][21]. In the top-down approach, bulk materials are decomposed and converted into QDs through physical, chemical, or electrochemical methods.…”

Quantum dots derived from two-dimensional transition metal dichalcogenides: synthesis, optical properties and optoelectronic applications