Giant crystal-electric-field effect and complex magnetic behavior in single-crystalline CeRh3Si2

TL;DR

This study reveals a giant crystal-electric-field effect and complex magnetic behavior in single-crystalline CeRh3Si2, characterized by strong anisotropy, antiferromagnetic order, and intricate magnetic phase transitions, supported by experimental and theoretical analyses.

Contribution

It provides a comprehensive investigation combining experimental measurements and ab-initio calculations to elucidate the magnetic and electronic properties of CeRh3Si2, highlighting the strong crystal-electric-field effects.

Findings

Strong anisotropic physical properties across temperature range

Antiferromagnetic order at TN = 4.70 K with complex magnetic phases

Crystal-electric field splitting exceeds 5700 K

Abstract

Single-crystalline CeRh3Si2 was investigated by means of x-ray diffraction, magnetic susceptibility, magnetization, electrical resistivity, and specific heat measurements carried out in wide temperature and magnetic field ranges. Moreover, the electronic structure of the compound was studied at room temperature by cerium core-level x-ray photoemission spectroscopy (XPS). The physical properties were analyzed in terms of crystalline electric field and compared with results of ab-initio band structure calculations performed within the density functional theory approach. The compound was found to crystallize in the orthorhombic unit cell of the ErRh3Si2 type (space group Imma -- No.74, Pearson symbol: oI24) with the lattice parameters: a = 7.1330(14) A, b = 9.7340(19) A, and c = 5.6040(11) A. Analysis of the magnetic and XPS data revealed the presence of well localized magnetic moments of trivalent cerium ions. All physical properties were found to be highly anisotropic over the whole temperature range studied, and influenced by exceptionally strong crystalline electric field with the overall splitting of the 4f1 ground multiplet exceeding 5700 K. Antiferromagnetic order of the cerium magnetic moments at TN = 4.70(1)K and their subsequent spin rearrangement at Tt = 4.48(1) K manifest themselves as distinct anomalies in the temperature characteristics of all investigated physical properties and exhibit complex evolution in an external magnetic field. A tentative magnetic B-T phase diagram, constructed for B parallel to the b-axis being the easy magnetization direction, shows very complex magnetic behavior of CeRh3Si2, similar to that recently reported for an isostructural compound CeIr3Si2. The electronic band structure calculations corroborated the antiferromagnetic ordering of the cerium magnetic moments and well reproduced the experimental XPS valence band spectrum.