High-temperature ferroelectric order and magnetoelectric coupling driven by the magnetic field cooling effect in R2BaCuO5(R=Er,Dy,Sm)

The high-temperature ferroelectric order and a remarkable magnetoelectric effect driven by the magnetic field cooling are reported in R2BaCuO5(R = Er, Dy, Sm) series. The ferroelectric (FE) orders are observed at much higher temperatures than their magnetic orders for all three members. The value of...

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Bibliographic Details
Published in:Physical review. B 2019-07, Vol.100 (1), p.014413
Main Authors: Indra, A, Mukherjee, S, Majumdar, S, Gutowski, O, Zimmermann, M V, Giri, S
Format: Article
Language:English
Subjects:
Cooling
Cooling effects
Copper
Coupling (molecular)
Curie temperature
Deoxidizing
Dysprosium compounds
Ferroelectric materials
Ferroelectricity
High temperature
Magnetic fields
Magnetism
Polarization
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Summary:The high-temperature ferroelectric order and a remarkable magnetoelectric effect driven by the magnetic field cooling are reported in R2BaCuO5(R = Er, Dy, Sm) series. The ferroelectric (FE) orders are observed at much higher temperatures than their magnetic orders for all three members. The value of FE Curie temperature (TFE) is considerably high as ~235 K with the polarization value (P) of ~1410μC/m2 for a 4 kV/cm poling field in the case of Er2BaCuO5, whereas the values of TFE and P are also promising as ~232 and ~992μC/m2 for Dy2BaCuO5, and ~184 K and ∼980μC/m2 for Sm2BaCuO5. The synchrotron diffraction studies of Dy2BaCuO5 confirm a structural transition at TFE to a polar Pna21 structure, which correlates the FE order. An unusual magnetoelectric coupling is observed below the R order for Er and Dy compounds and below the Cu order for Sm compound, when the pyroelectric current is recorded only with the magnetic field both in heating and cooling cycles, i.e., the typical magnetic field cooled effect. The magnetic field cooled effect driven emergence of polarization is ferroelectric in nature, as it reverses due to the opposite poling field.
ISSN:2469-9950
2469-9969
DOI:10.1103/PhysRevB.100.014413