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Spin waves and spin-state transitions in a ruthenate high-temperature antiferromagnet.

H SuzukiH GretarssonH IshikawaK UedaZ YangH LiuH KimD KukustaAlexander YareskoM MinolaJ A SearsS FrancoualH-C WilleJürgen NussHidenori TakagiB J KimGiniyat KhaliullinHasan YavasBernhard Keimer
Published in: Nature materials (2019)
Ruthenium compounds serve as a platform for fundamental concepts such as spin-triplet superconductivity1, Kitaev spin liquids2-5 and solid-state analogues of the Higgs mode in particle physics6,7. However, basic questions about the electronic structure of ruthenates remain unanswered, because several key parameters (including Hund's coupling, spin-orbit coupling and exchange interactions) are comparable in magnitude and their interplay is poorly understood, partly due to difficulties in synthesizing large single crystals for spectroscopic experiments. Here we introduce a resonant inelastic X-ray scattering (RIXS)8,9 technique capable of probing collective modes in microcrystals of 4d electron materials. We observe spin waves and spin-state transitions in the honeycomb antiferromagnet SrRu2O6 (ref. 10) and use the extracted exchange interactions and measured magnon gap to explain its high Néel temperature11-16. We expect that the RIXS method presented here will enable momentum-resolved spectroscopy of a large class of 4d transition-metal compounds.
Keyphrases
  • room temperature
  • transition metal
  • single molecule
  • density functional theory
  • solid state
  • ionic liquid
  • high temperature
  • molecular dynamics simulations
  • mass spectrometry
  • single cell
  • contrast enhanced