Light-controlled room temperature ferromagnetism in vanadium-doped tungsten diselenide semiconducting monolayers

TL;DR

This study demonstrates light-controlled room temperature ferromagnetism in vanadium-doped tungsten diselenide monolayers, enabling potential applications in low-power 2D spintronic devices.

Contribution

It introduces a novel method to induce and control ferromagnetism in 2D semiconductors using light at room temperature, combining experimental and theoretical insights.

Findings

Light intensity modulates magnetic permeability of V-WS2 monolayers.

Magnetism mediated by excess holes and trapped carriers.

Potential for low-power, room-temperature spintronic devices.

Abstract

Atomically thin transition metal dichalcogenide (TMD) semiconductors hold enormous potential for modern optoelectronic devices and quantum computing applications. By inducing long-range ferromagnetism (FM) in these semiconductors through the introduction of small amounts of a magnetic dopant, it is possible to extend their potential in emerging spintronic applications. Here, we demonstrate light-mediated, room temperature (RT) FM, in V-doped WS2 (V-WS2) monolayers. We probe this effect using the principle of magnetic LC resonance, which employs a soft ferromagnetic Co-based microwire coil driven near its resonance in the radio frequency (RF) regime. The combination of LC resonance with an extraordinary giant magneto-impedance effect, renders the coil highly sensitive to changes in the magnetic flux through its core. We then place the V-WS2 monolayer at the core of the coil where it is excited with a laser while its change in magnetic permeability is measured. Notably, the magnetic permeability of the monolayer is found to depend on the laser intensity, thus confirming light control of RT magnetism in this two-dimensional (2D) material. Guided by density functional calculations, we attribute this phenomenon to the presence of excess holes in the conduction and valence bands, as well as carriers trapped in the magnetic doping states, which in turn mediates the magnetization of the V-WS2 monolayer. These findings provide a unique route to exploit light-controlled ferromagnetism in low powered 2D spintronic devices capable of operating at RT.