The role of magnetoelastic coupling and magnetic anisotropy in MnTiO3

Abstract

We report the thermodynamic properties studied by thermal expansion, magnetostriction, magnetisation, and specific heat measurements as well as the low-energy magnetic excitations of \ and investigate how magneto-elastic coupling and magnetic anisotropy affect the evolution of long-range order and the magnetic phase diagram. Specifically, we utilise high-resolution capacitance dilatometry and antiferromagnetic resonance (AFMR) studies by means of high-frequency electron spin resonance (HF-ESR) spectroscopy. The role of anisotropy is reflected by spin-reorientation at BSF~ 6~T and a corresponding sign change in ∂ T N/∂ B. Analysis of the AFMR modes enables us to establish the zero-field excitation gap as well as its temperature dependence. We derive the effective anisotropy field BA = 0.16(1)~T which predominately originates from out-of-plane nearest-neighbour dipole-dipole interactions. Despite the nearly fully quenched orbital moment, our data show pronounced thermal expansion and magnetostriction anomalies at T N and BSF , respectively, which allows the experimental determination of sizable uniaxial pressure dependencies, i.e., ∂ B SF/∂ p c = -0.20(2)~T/GPa, ∂ T N/ ∂ pb = 0.69(12)~K/GPa, and ∂ T N/ ∂ pc = -2.0(4)~K/GPa. Notably, short-range magnetic order appears up to at least 3T N , as indicated by anisotropic lattice distortion, the violation of a constant Gr\"uneisen behavior, and the presence of local magnetic fields detected by HF-ESR.

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