Abstract
In the last several decades, significant efforts have been devoted to two-dimensional (2D) materials on account of their optical properties that have numerous applications in the optoelectronic world in the range of light-emitting diodes, optical sensors, solar energy conversion, photo-electrochemical cells, photovoltaic solar cells, and even the biomedical sector. First, we provide an outline of linear optical properties of 2D materials such as graphene, TMDs, h-BN, MXenes, perovskite oxide, and metal-organic framework. Then, we discuss the optoelectronic properties of the 2D materials. Along with these, we also highlight the important efforts in developing 2D optical materials with intensive emission properties at a broad wavelength from ultraviolet to near-infrared. The origin of this tunable emission has been discussed decoratively. Thickness and layer-dependent optical properties have been highlighted and are explained through surface defects, strain, vacancy, doping, and dangling bonds emerging due to structural change in the material. The linear and nonlinear optical properties in 2D MXene and perovskite oxides are also impressive due to their potential applications in next-generation devices with excellent optical sensitivity. Finally, technological innovations, challenges, and possible tuning of defects and imperfections in the 2D lattice are discussed.
Highlights
Optical properties have been one of the most fascinating and functional aspects of any nanomaterial
The review shows that while the 2D transition metal di-chalcogenides (TMDs), MO, and MXens can be a part of the endless amount of work in optics, several modifications are needed for the enhancement of optoelectronics applications in modern electronics
The 3D printing technology can be utilized to build 2D materials optoelectronics circuits to tune the properties of the device
Summary
Optical properties have been one of the most fascinating and functional aspects of any nanomaterial. PL emission spectra of MoS2 and WS2 were studied on two different substrates, and it is observed that with hBN, PL emission shows more narrowing behavior The optical absorption in the visible region with high electron and hole mobilities was observed for the monolayer of GeTe. It shows a large bandgap which is straintunable compared to its bulk form (Qiao et al, 2018).
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