Review on magnetic and related properties of RTX compounds

TL;DR

This review comprehensively summarizes the diverse magnetic, electrical, and structural properties of RTX compounds, highlighting recent interest due to their magnetocaloric effect and magnetoresistance, and covering experimental and theoretical insights.

Contribution

It provides a detailed overview of the structural, magnetic, and electronic properties of RTX compounds, emphasizing recent findings and the variety of physical phenomena exhibited by these materials.

Findings

RTX compounds exhibit a wide range of magnetic and electrical properties.

Many RTX compounds show large magnetocaloric effects and magnetoresistance.

Structural and magnetic transitions are influenced by composition and annealing.

Abstract

RTX (R=rare earths, T= 3d/4d/5d, transition metals such as Sc, Ti, Mn, Fe, Co, Ni, Cu, Ru, Rh, Pd, Ag, Os, Ir, Pt, Au, and X=p-block elements such as Al, Ga, In, Si, Ge, Sn, As, Sb, Bi) series is a huge family of intermetallics compounds. These compounds crystallize in different crystal structures depending on the constituents. Though these compounds have been known for a long time, they came to limelight recently in view of the large magnetocaloric effect (MCE) and magnetoresistance (MR) shown by many of them. Most of these compounds crystallize in hexagonal and tetragonal crystal structures. Some of them show crystal structure modification with annealing temperature; while a few of them show iso-structural transition in the paramagnetic regime. Their magnetic ordering temperatures vary from very low temperatures to temperatures well above room temperature (~510 K). Depending on the crystal structure, they show a variety of magnetic and electrical properties. These compounds have been characterized by means of a variety of techniques/measurements such as x-ray diffraction, neutron diffraction, magnetic properties, heat capacity, magnetocaloric properties, electrical resistivity, magnetoresistance, thermoelectric power, thermal expansion, Hall effect, optical properties, XPS, M\"ossbauer spectroscopy, ESR, {\mu}SR, NMR, NQR etc. Some amount of work on theoretical calculations on electronic structure, crystal field interaction and exchange interactions has also been reported. The interesting aspect of this series is that they show a variety of physical properties such as Kondo effect, heavy fermion behavior, spin glass state, intermediate valence, superconductivity, multiple magnetic transitions, metamagnetism, large MCE, large positive as well as negative MR, spin orbital compensation, magnetic polaronic behavior, pseudo gap effect etc.