Emerging Enhancement and Regulation Strategies for Ferromagnetic 2D Transition Metal Dichalcogenides

Two-dimensional transition metal dichalcogenides (2D TMDs) present promising applications in various fields such as electronics, optoelectronics, memory devices, batteries, superconductors, and hydrogen evolution reactions due to their regulable energy band structures and unique properties. For emerging spintronics applications, materials with excellent room-temperature ferromagnetism are required. Although most transition metal compounds do not possess room-temperature ferromagnetism on their own, they are widely modified by researchers using the emerging strategies to engineer or modulate their intrinsic properties. This paper reviews recent enhancement approaches to induce magnetism in 2D TMDs, mainly using doping, vacancy defects, composite of heterostructures, phase modulation, and adsorption, and also by electron irradiation induction, O plasma treatment, etc. On this basis, the produced effects of these methods for the introduction of magnetism into 2D TMDs are compressively summarized and constructively discussed. For perspective, research on magnetic doping techniques for 2D TMDs materials should be directed toward more reliable and efficient directions, such as exploring advanced design strategies to combine dilute magnetic semiconductors, antiferromagnetic semiconductors, and superconductors to develop new types of heterojunctions; and advancing experimentation strategies to fabricate the designed materials and enable their functionalities with simultaneously pursuing the upscalable growth methods for high-quality monolayers to multilayers.

Automated summary

Two-dimensional transition metal dichalcogenides (2D TMDs) have promising applications in various fields, such as electronics, optoelectronics, memory devices, batteries, superconductors, and hydrogen evolution reactions. This paper reviews recent enhancement approaches to induce magnetism in 2D TMDs, including doping, vacancy defects, heterostructure composites, phase modulation, adsorption, electron irradiation, and O plasma treatment. The effects of these methods on introducing magnetism into 2D TMDs are summarized and discussed. For future research, more reliable and efficient techniques, such as exploring advanced design strategies and advancing experimentation strategies, should be directed towards magnetic doping in 2D TMDs materials.