Influence of Ni/Mn cation order on the spin-phonon coupling in multifunctional La2NiMnO6 epitaxial films by polarized Raman spectroscopy

TL;DR

This study investigates how Ni/Mn cation order affects spin-phonon coupling in La2NiMnO6 films, revealing that cation ordering influences phonon behavior and spin interactions, with implications for multifunctional material properties.

Contribution

It provides a comparative analysis of cation-ordered, disordered, and mixed La2NiMnO6 films using polarized Raman spectroscopy and magnetometry, highlighting the impact of cation order on spin-phonon coupling.

Findings

Long-range cation order causes Raman peak splitting.

Spin-phonon coupling is stronger in ordered films.

Disordered films show suppressed phonon softening.

Abstract

We report the influence of Ni/Mn ordering on the spin-phonon coupling in multifunctional La2NiMnO6. Three types of films with different levels of structural order, including long-range Ni/Mn cation order, cation disorder, and an admixture of the ordered and disordered phases, are compared by polarized micro-Raman spectroscopy and magnetometry. Each film displays a strong dependence on the polarization configuration and a unique set of Raman active phonon excitations. Long-range cation ordering results in the splitting of Raman active phonon peaks because of Brillouin zone folding and lowering symmetry. Phonon mode softening begins clearly at a distinct temperature for each sample revealing a strong spin-lattice interaction. It follows closely the magnetization curve in ordered films. Unlike the admixture and the ordered films, softening behavior is strongly suppressed in the cation-disordered films. These differences may be understood based on the variation in amplitude of the spin-spin correlation functions due to the local Ni/Mn cation ordering.