A μSR study of the ruthenium perovskites ACu3Ru4O12 with A Ca, Pr, Nd

The metallic ruthenium perovskites ACu3Ru4O12 with A Ca, Pr,Nd were investigated by zero field (ZF) and weak transverse field (TF) muon spin rotation/relaxation (μSR) spectroscopy. The ZF spectra for CaCu3Ru4O12 show pure static Gaussian Kubo-Toyabe relaxation arising from the interaction between th...

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Bibliographic Details
Published inJournal of physics. Conference series Vol. 551; no. 1
Main Authors Kalvius, G M, Hartmann, O, Günther, A, Krimmel, A, Loidl, A, Wäppling, R, Sedlak, K, Scheuermann, R
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 16.12.2014
Subjects
Calcium
Magnetic moments
Muon spin relaxation
Muon spin rotation
Neodymium
Neutron diffraction
Parameters
Perovskites
Physics
Praseodymium
Ruthenium
Spectra
Spectrum analysis
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Summary:The metallic ruthenium perovskites ACu3Ru4O12 with A Ca, Pr,Nd were investigated by zero field (ZF) and weak transverse field (TF) muon spin rotation/relaxation (μSR) spectroscopy. The ZF spectra for CaCu3Ru4O12 show pure static Gaussian Kubo-Toyabe relaxation arising from the interaction between the muon spin and the nuclear moments of the Cu ions. This confirms that no atomic magnetic moment exists. A sudden increase of the lattice parameter a when heating above ~150 K had previously been detected by neutron diffraction. The root mean square field at the muon site Brms was found to be 0.15 mT independent of temperature, in particular around 150 K. Also, no change of spectral parameters is seen in the weak TF data in that temperature range. Those findings imply that the structural change around 150 K takes place without noticeably shifting atomic positions. The spectra for PrCu3Ru4O12 and NdCu3Ru4O12 are dominated by the interaction with the dynamic rare earth moments. The analysis requires the use of the electron-nuclear double relaxation formalism. The electronic part shows simple exponential relaxation typical for a paramagnet. It features, with reducing the temperature a steep increase of paramagnetic relaxation rate as is characteristic for an approach to a magnetic spin freezing transition from above. That result suggests that the magnetic ground states of PrCu3Ru4O12 and NdCu3Ru4O12 are spin frozen states, although bulk magnetic data give no direct evidence in that direction.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/551/1/012015