TMR transition and highly sensitive pressure sensors based on magnetic tunnel junctions with black phosphorus barrier

TL;DR

This paper theoretically investigates black phosphorus-based magnetic tunnel junctions, revealing a tunable TMR transition and proposing highly sensitive pressure sensors with advantages like high sensitivity and fast response, advancing spintronic and sensor technologies.

Contribution

It introduces the concept of pressure-sensitive MTJs with black phosphorus barriers, demonstrating TMR transition phenomena and designing novel pressure sensors with superior performance.

Findings

TMR can transition from finite to infinite with band gap tuning.

Pressure can significantly alter TMR, indicating high pressure sensitivity.

Proposed pressure sensors outperform conventional ones in sensitivity and response speed.

Abstract

Black phosphorus is a promising material to serve as the barrier of magnetic tunnel junctions (MTJs) due to the weak van der Waals interlayer interactions. In particular, the special band features of black phosphorus may bring intriguing physical characteristics. Here, we study theoretically the effect of band gap tunability of black phosphorus on the MTJs with black phosphorus barrier. It is found that, the tunneling magnetoresistance (TMR) may achieve a transition from finite value to infinity owing to the variation of the band gap of black phosphorus. Combining with the latest experimental results of the pressure-induced band gap tunability, we further investigate the pressure effect of TMR in the MTJs with black phosphorus barrier. The calculations show that the pressure sensitivity can be quite high under appropriate parameters. Physically, the high sensitivity originates from the TMR transition phenomenon. To take advantage of the high pressure sensitivity, we propose and design a detailed structure of highly sensitive pressure sensors based on MTJs with black phosphorus barrier, whose working mechanism is basically different from the convential pressure sensors. The present pressure sensors possess four advantages and benifits: (1) high sensitivity, (2) well anti-interference, (3) high spatial resolution, and (4) fast response speed. Our study may advance new research area for both the MTJs and pressure sensors.