Harmonic magneto-dielectric study in doped-, double-, and layered-perovskites

Harmonic magneto-dielectricity studied for the perovskite systems—Pb0.98Gd0.02(Mg1/3Nb2/3)0.995O3 (PGMN), La0.95Ca0.05CoO3 (LCCO), La2NiMnO6 (LNMO), and Ca3Mn2O7 (CMO), precisely characterizes intricately polarized phases. In magnetically co-doped PGMN, the first-harmonic signal ( χ 2 ′ ) manifests...

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Bibliographic Details
Published in:Journal of applied physics 2020-04, Vol.127 (15)
Main Authors: Sahlot, Pooja, Pandey, Suchita, Pandey, Adityanarayan, Awasthi, A. M.
Format: Article
Language:English
Subjects:
Antiferromagnetism
Applied physics
Charge transfer
Chi-square test
Ferroelectric materials
Ferroelectricity
Ferromagnetism
Manganese
Perovskites
Phases
Relaxors
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Summary:Harmonic magneto-dielectricity studied for the perovskite systems—Pb0.98Gd0.02(Mg1/3Nb2/3)0.995O3 (PGMN), La0.95Ca0.05CoO3 (LCCO), La2NiMnO6 (LNMO), and Ca3Mn2O7 (CMO), precisely characterizes intricately polarized phases. In magnetically co-doped PGMN, the first-harmonic signal ( χ 2 ′ ) manifests finite polarization P(H) below 270 K, corroborated by the measured remnant P–E traces. The second harmonic ( χ 3 ′ ) reveals the effect of random E-fields, causing electrical vitreousity. In spin-state LCCO, across the 65K-start of intermediate- (IS) to low-spin (LS) transition, harmonic susceptibilities evidence IS/LS-interfacial hyper-polarizations, and ac-/dc- conductivities exhibit mechanism-changeovers. In charge-transfer LNMO, dual magneto-electricity due to Ni2+ ↔ Mn4+ charge-hopping (intrinsic) and Maxwell–Wagner (fictitious) polarizations gets distinguished via χ 2 ′. In hybrid improper ferroelectric (HIF) CMO, while the χ 2 , 3 ′-signals clearly evidence stabilization of the ferroelectric state below 50 K, χ 3 ′ and ɛ* discern the super-paraelectric, coupled-relaxor, and glassy phases, magneto-electrically coexistent with short-range spin-correlations, antiferromagnetic, and weak-ferromagnetic states, respectively. Our results on a variety of perovskites establish harmonics' exclusivity in revealing novel phases and superiority in divulging subtly variant states, either escaping detection or rendered indescript by usual electrical characterizations.
ISSN:0021-8979
1089-7550
DOI:10.1063/1.5145383