Structural, magnetic and dielectric properties in 3d-5d based Sr2FeIrO6 thin films

The structural, magnetic and dielectric properties have been investigated in 3d-5d based double perovskite Sr2FeIrO6 thin films deposited by pulse laser deposition technique. To understand the effect of strain, epitaxial films are grown with varying thickness as well as on different substrates i.e.,...

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Bibliographic Details
Published in:Journal of physics. Condensed matter 2020-12, Vol.32 (50)
Main Authors: Kharkwal, K C, Patel, Roshan Kumar, Asokan, K, Pramanik, A K
Format: Article
Language:English
Subjects:
dielectric study
double perovskite
magnetism
spin-orbit coupling
thin film and multilayer
x-ray absorption spectroscopy
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Summary:The structural, magnetic and dielectric properties have been investigated in 3d-5d based double perovskite Sr2FeIrO6 thin films deposited by pulse laser deposition technique. To understand the effect of strain, epitaxial films are grown with varying thickness as well as on different substrates i.e., SrTiO3 (100) and LaAlO3 (100). The films with highest thickness are found to be more relaxed. Atomic force microscope images indicate all films are of good quality where grain sizes increase with increase in film thickness. X-ray absorption (XAS) spectroscopy measurements indicate a Ir5+ charge state in present films while providing a detailed picture of hybridization between Fe/Ir-d and O-p orbitals. The bulk antiferromagnetic transition is retained in films though the transition temperature shifts to higher temperature. Both dielectric constant (ϵr) and loss (tan  δ) show change around the magnetic ordering temperatures of bulk Sr2FeIrO6 indicating a close relation between dielectric and magnetic behaviors. A Maxwell-Wagner type relaxation is found to follow over whole frequency range down to low temperature in present film. On changing the substrate i.e., LaAlO3 (100), the ϵr(T) and (tan  δ(T)) show almost similar behavior but ϵr shows a higher value which is due to an increased strain coming from high mismatch of lattice parameters.
ISSN:0953-8984
1361-648X
DOI:10.1088/1361-648X/abb2f5