Helical Antiferromagnetic Ordering in Lu{1-x}Sc{x}MnSi (x = 0, 0.25, 0.50)

TL;DR

This study investigates the magnetic and electronic properties of Lu{1-x}Sc{x}MnSi compounds, revealing antiferromagnetic ordering, spin reorientation transitions, and composition-dependent magnetic structures through comprehensive experimental measurements.

Contribution

It provides the first detailed analysis of magnetic structures and transitions in Lu{1-x}Sc{x}MnSi, combining experimental data with theoretical modeling.

Findings

Long-range antiferromagnetic transitions at specific temperatures for each composition.

Observation of spin reorientation transitions suppressed by magnetic field.

Enhanced electronic heat capacity indicating correlated electron behavior.

Abstract

Polycrystalline samples of Lu{1-x}Sc{x}MnSi (x= 0, 0.25, 0.50) are studied using powder x-ray diffraction (XRD), heat capacity Cp, magnetization M, magnetic susceptibility chi, and electrical resistivity rho measurements versus temperature T and magnetic field H. This system crystallizes in the primitive orthorhombic TiNiSi-type structure (space group Pnma) as previously reported. The rho(T) data indicate metallic behavior. The Cp(T), chi(T), and rho(T) measurements consistently indicate long-range antiferromagnetic (AF) transitions with AF ordering temperatures TN = 246, 215 and 188 K for x = 0, 0.025 and 0.50, respectively. A second transition is observed at somewhat lower T for each sample from the chi(T) and rho(T) measurements, which we speculate are due to spin reorientation transitions; these second transitions are completely suppressed in H = 5.5 T. The Cp data below 10 K for each composition indicate an enhanced Sommerfeld electronic heat capacity coefficient for the series in the range gamma = 24 to 29 mJ/mol K^2. The chi(T) measurements up to 1000 K were fitted by local-moment Curie-Weiss behaviors which indicate a low Mn spin S ~ 1. The chi data below TN are analyzed using the Weiss molecular field theory for a planar noncollinear helical AF structure with a composition-dependent pitch, following the previous neutron diffraction work of Venturini et al. [J. Alloys Compd. 256, 65 (1997)]. Within this model, the fits indicate a turn angle between Mn moments along the helix axis of ~100 degrees or ~145 degrees, either of which indicate dominant AF interactions between the Mn spins in the Lu{1-x}Sc{x}MnSi series of compounds.