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Spinel ferrites having conductive grains, resistive interfacial boundaries and relaxation mechanism for possible supercapacitor applications

Muhammad Zulqarnain, S.S. Ali, Muhammad Atif Yaqub, Caihua Wan, M.I. Khan, Muhammad Riaz, A. Laref, Mongi Amami

2024Results in Physics13 citationsDOIOpen Access PDF

Abstract

Linear increase in crystallite size (16–24 nm) of MnxZn1−xFe2O4 nanostructures and mixed behavior of lattice constant (8.429–8.462 Å) is reported. The system exhibits considerable promise for microwave applications due to its elevated dielectric constants and minimal dispersion losses from 20 Hz to 20 MHz. With x = 0.75, sample is good for energy storage devices like supercapacitors due to large specific surface area (53 m2/g) and dielectric constant. These samples exhibit maximum relaxation times ranging from 1.97 × 10−7 s to 2.43 × 10−4 s, with corresponding relaxation energy values spanning from 159.22 meV to 341 meV for x = 0 and x = 1 samples. The Cole-Cole plots reveal that grains exhibit conductive behavior at lower frequencies, while grain boundaries contribute significantly to the resistive behavior. Additionally, we have introduced Bode diagrams and equivalent electronic circuit models for the first time, offering valuable insights into the electrical behavior of the nanomaterial samples.

Topics & Concepts

Materials scienceCrystalliteDielectricGrain boundaryResistive touchscreenCondensed matter physicsLattice constantSpinelDielectric lossElectrical conductorRelaxation (psychology)SupercapacitorHigh-κ dielectricTime constantNanomaterialsGrain sizeAnalytical Chemistry (journal)NanotechnologyComposite materialOptoelectronicsCapacitanceElectrodeMicrostructureChemistryOpticsElectrical engineeringPhysicsPsychologyPhysical chemistrySocial psychologyChromatographyEngineeringDiffractionMetallurgyMagnetic Properties and Synthesis of FerritesElectromagnetic wave absorption materialsMultiferroics and related materials