IJCMP | Cation distribution of Ni2+ and Mg2+ ions improve structure and Magnetic Properties of Spinel Ferrites

Indexing and Abstracting

Cation distribution of Ni2+ and Mg2+ ions improve structure and Magnetic Properties of Spinel Ferrites

Pranali K. Tembhurne , Shrikant M Suryawanshi , Kishor G. Rewatkar , Dilip S. Chaudhary , Sanjay J. Dhoble

International Journal of Chemistry, Mathematics And Physics(IJCMP), Vol-5,Issue-6, November - December 2021, Pages 7-13 , 10.22161/ijcmp.5.6.2

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Article Info: Received: 09 Oct 2021; Received in revised form: 13 Nov 2021; Accepted: 21 Nov 2021; Available online: 30 Nov 2021

Abstract:

In the present work, ferromagnetic Ni is slightly substituted for diamagnetic Mg spinal ferrites. The effect of Ni doping on the structural and magnetic properties of ferrites material in the form of NixMg1-xFe2O4 (x = 0.1,0.15,0.2,0.25, .0.3,0.35) has been the study. The Sol-gel auto Combustion method used to combine these substances uses urea as fuel. Sintered samples were shown using X-ray diffraction, Fourier Transform Infrared spectroscopy (FTIR) and a vibrating magnetometer sample. X-ray diffraction revealed that all the composite samples were pure cubic spinel arrays with a Fd3m space band and a permanent lattice that varied with Ni concentrations. the distribution of Ni2 + ions and Mg2+ ions in spinel ferrites indicates various changes in parameters such as tetrahedral ionic radius (rA), octahedral ionic radius (rB), hopping length (LA and LB). Fourier Transform Infrared (FT-IR) simulations showed wire vibration at the tetrahedral site and Octahedral site. spinel ferrites M-H curves are recorded at room temperature indicating normal hysteresis loop indicating the magnetic field.

Keywords:

Cation distribution, Magnetic Properties, Spinel Ferrites, nanobiotechnology, X-ray diffraction.

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