Materials and possible mechanisms of extremely large magnetoresistance: A review

TL;DR

This review discusses the physical mechanisms behind large and extremely large magnetoresistance in various materials, highlighting recent discoveries, potential applications, and the importance of understanding underlying physics for device development.

Contribution

It provides a comprehensive overview of the mechanisms and recent advances in understanding extremely large magnetoresistance, integrating topological and material science perspectives.

Findings

Large MR materials like manganites exhibit colossal MR up to -90%.

Recent XMR systems show positive MR of 10^3-10^8%, persistent under high magnetic fields.

Multiple mechanisms, including electron-hole compensation and topological effects, contribute to XMR.

Abstract

Magnetoresistance (MR) is a characteristic that the resistance of a substance changes with the external magnetic field, reflecting various physical origins and microstructures of the substance. A large MR, namely a huge response to a low external field, has always been a useful functional feature in industrial technology and a core goal pursued by physicists and materials scientists. Conventional large MR materials are mainly manganites, whose colossal MR (CMR) can be as high as -90%. The dominant mechanism is attributed to spin configuration aligned by the external field, which reduces magnetic scattering and thus resistance. In recent years, some new systems have shown an extremely large unsaturated MR (XMR). Unlike ordinary metals, the positive MR of these systems can reach 103-108% and is persistent under super high magnetic fields. The XMR materials are mainly metals or semimetals, distributed in high-mobility topological or non-topological systems, and some are magnetic, which suggests a wide range of application scenarios. Various mechanisms have been proposed for the potential physical origin of XMR, including electron-hole compensation, steep band, ultrahigh mobility, high residual resistance ratio, topological fermions, etc. It turns out that some mechanisms play a leading role in certain systems, while more are far from clearly defined. In addition, the researches on XMR are largely overlapped or closely correlated with other recently rising physics and materials researches, such as topological matters and two-dimensional (2D) materials, which makes elucidating the mechanism of XMR even more important. Moreover, the disclosed novel properties will lay a broad and solid foundation for the design and development of functional devices. In this review, we will discuss several aspects in the following order: ...