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Effects of Cu and Ni co-doping on magnetic, photocatalytic and dielectric properties of Co3O4 nanoparticles

Muhammad Qasim, K. Nadeem, Muhammad Shahid, M. Zareef Khan, Ablikim Baqi

2025Ceramics International12 citationsDOIOpen Access PDF

Abstract

Magnetic, photocatalytic and dielectric properties of Cu 2+ and Ni 2+ co-doped Co 3 O 4 nanoparticles (NPs) have been studied in detail. XRD analysis confirmed the single pure phase formation of Co 3 O 4 NPs and co-doped (CN26, CN44 and CN62) NPs samples. The average crystallite size increases from 16.5 to 30.9 nm with co-doping due to stress and strain induced by the co-dopants. FTIR analysis revealed the formation of desired molecular bands especially at 578 cm −1 ( v 1 ) and 661 cm −1 ( v 2 ) originating from stretching vibrations caused by Co-O bonds confirming the formation of spinel oxide structure. Tauc plots from UV–Vis spectroscopy showed increased bandgap from 3.68 to 3.82 eV with co-doping due to Burstein-Moss effect. Magnetic measurements revealed the presence of weak ferromagnetism (FM) in antiferromagnetic (AFM) Co 3 O 4 NPs with co-doping due to the increased FM exchange interactions caused by the incorporation of Cu 2+ and Ni 2+ ions. A maximum magnetization and coercivity were observed in CN44 sample (with equal percentage of dopants) which is due to increased magnetic interactions caused by co-dopants. In ZFC/FC curves of undoped Co 3 O 4 NPs, a broad AFM peak is observed at 42 K with overlapped ZFC/FC corresponds to the freezing temperature of AFM spins. In co-doped samples, the weak FM behavior is evident by the splitting of ZFC/FC curves at low temperatures. The increase in magnetization with co-doping can be attributed to both Cu/Ni doping and uncompensated surface spins. In photocatalysis , the degradation rate (for methyl orange dye) increases from 84.23 to 89.39 % with co-doping which is due to increase in bandgap and decrease in electron-hole recombination. A decrease in dielectric constant was observed by co-doping which is caused by the conducting nature of both the co-dopants. Dielectric losses were increased with co-doping because of increased charge population available for polarization.

Topics & Concepts

Materials scienceDielectricDopingPhotocatalysisNanoparticleChemical engineeringNanotechnologyOptoelectronicsCatalysisBiochemistryChemistryEngineeringMagnetic Properties and Synthesis of FerritesZnO doping and propertiesCopper-based nanomaterials and applications
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