Single crystal growth and characterization of antiferromagnetically ordering EuIn$_2$

TL;DR

This study reports the growth and detailed magnetic characterization of EuIn$_2$, revealing complex incommensurate magnetic structures and multiple magnetic transitions, supported by various experimental techniques and DFT calculations.

Contribution

First comprehensive single crystal growth and magnetic analysis of EuIn$_2$, demonstrating incommensurate magnetic order and multiple phase transitions.

Findings

Identified three magnetic transitions at 14.2 K, 12.8 K, and 11 K.

Observed incommensurate sinusoidal magnetic structure below 14 K.

Magnetic propagation vector varies with temperature and locks at low temperatures.

Abstract

We report the single crystal growth and characterization of EuIn$_2$, a magnetic topological semimetal candidate according to our density functional theory (DFT) calculations. We present results from electrical resistance, magnetization, M\"ossbauer spectroscopy, and X-ray resonant magnetic scattering (XRMS) measurements. We observe three magnetic transitions at $T_{\text{N}1}\sim 14.2~$K, $T_{\text{N}2}\sim12.8~$K and $T_{\text{N}3}\sim 11~$K, signatures of which are consistently seen in anisotropic temperature dependent magnetic susceptibility and electrical resistance data. M\"ossbauer spectroscopy measurements on ground crystals suggest an incommensurate sinusoidally modulated magnetic structure below the transition at $T_{\text{N}1}\sim 14~$K, followed by the appearance of higher harmonics in the modulation on further cooling roughly below $T_{\text{N}2}\sim13~$K, before the moment distribution squaring up below the lowest transition around $T_{\text{N}3}\sim 11~$K. XRMS measurements showed the appearance of magnetic Bragg peaks below $T_{\text{N}1}\sim14~$K, with a propagation vector of $\bm{\tau}$ $=(\tau_h,\bar{\tau}_h,0)$, with $\tau_h$varying with temperature, and showing a jump at $T_{\text{N}3}\sim11$~K. The temperature dependence of $\tau_h$ between $\sim11$~K and $14$~K shows incommensurate values consistent with the M\"{o}ssbauer data. XRMS data indicate that $\tau_h$ remains incommensurate at low temperatures and locks into $\tau_h=0.3443(1)$.