Investigation on structural, electrical and magnetic properties of titanium substituted cobalt ferrite nanocrystallites

•TixCo1−xFe2O4 with (x = 0–0.075) via the sol-gel route is reported.•The effects of titanium substitution on the magnetic and electrical properties of cobalt ferrite are reported.•Crystallite size reduced from 34 nm (pure CoFe2O4) to 17 nm (Ti0.075Co0.925Fe2O4).•Minimizing of Raman modes (575 cm−1, 620 cm−1) correspond to Co-O motion inferred Ti ions replaced cobalt ions.•Magnetic moment, saturation magnetization, retentivity and coercivity increased with Ti substitution.•Impedance enhanced considerably since exchange interaction was weakened by Ti inclusion. The doping of parent compound with selective dopants usually enhances the properties of the parent compound. In this paper, titanium doped cobalt ferrite nanoparticles (Co1−xTixFe2O4 with x = 0–0.075) via the sol-gel route is reported. The effect of titanium ions on the properties of cobalt ferrite is detailed. Structural evolution is confirmed using XRD technique and the titanium ion induced changes are given in terms of lattice constant, grain size, X-ray density, tetrahedral and octahedral hopping length and tetrahedral and octahedral bond length. The X-ray diffraction pattern displayed the formation of cubic inverse spinal structure belonging to the Fd3m space group. FTIR analysis confirmed the presence of characteristic peaks of ferrites around 400 cm−1 and 600 cm−1. Raman spectroscopy revealed reduction in peak intensities of Raman active modes. SEM characterization had shown the formation of well resolved spherical particles. Elemental composition was evaluated by EDAX spectrum. TEM images also confirmed the spherical morphology of the nanocrystallites and crystallite size calculated is in agreement with that calculated from the XRD analysis. The SAED pattern shows uniform fringes of width 0.428 nm belonging (222) plane. The diffraction pattern of HRTEM confirmed cubic spinel structure of the samples. Magnetic properties are evaluated from room temperature hysteresis loops. Increase in the saturation magnetization and coercivity was observed with increasing titanium content. Gradual increase in impedance with the increase in titanium concentration was estimated by impedance spectroscopy.