Synthesis and Characterization of Cobalt Ferrite through Co-Precipitation Technique
S. Nithiyanantham, Selvaraj Viviliya, Somasundaram Anandhan, Sreepathi Mahalakshmi, Kalyanasundaram, L Gabriel, A Mariella, C Cynthia, B Cabriel, L Jochen, B Elisa, T Bastami, M Entezari, Q Hu, S Hartono, S Qiao, S Supriya, S Kumar, M Kar, M Sivakumar, S Kanagesan, V Umapathy, K Chinnaraj, S Nithiyanantham, M Sivakumar, S Kanagesan, K Chinnaraj, R Suresh Babu, S Nithiyanantham, Synthesis, Y Sumanth, R Sujatha, S Mahalakshmi, P Karthika, S Nithiyanantham, S Saravanan, Azagiri, S Hayrapetyan, H Khachatryan, A Nikumbh, R Pawar, D Nighot, G Gugale, M Sangale, M Khanvilkar, A Nagawade, Structural, Z Jiao, X Geng, M Wu, Y Jiang, B Zhao, V Kiran, S Sumathi, S Mahalakshmi, R Jayasri, S Nithiyanantham, S Swetha, K Santhi, M Mustaq, M Imran, S Bashir, F Kanwal, L Mitu, Synthesis, O Rahman, S Mohapatra, S Ahmad, A Raut, R Barkule, D Shengule, K Jadhav, A Kalam, A Al-Sehemi, M Assiri, G Du, T Ahmad, I Ahmad, M Pannipara, G Meenal, D Anushree, M Satyabratha, D Dipankar, D Anindya
Abstract
The device formation in current technology demands effective magnetic materials. Cobalt ferrite nanoparticles were synthesized by the co–precipitations method using the precursor materials (Fe(No3)3 9H2O) and (Co(NO3)2 6H2O). X-ray diffraction (XRD), Fourier Transform Infrared Spectroscopy (FTIR) analysis, and UV–Visible absorption spectral studies were used to analyze the structural, chemical/functional groups with possible stretching and optical bandgap properties of the CoFe2O4 powder. XRD results designate that the resultant particles are crystalline, pure single-phase spinel structure. From the FTIR analysis reveals that C-C, C=O stretching, and the shift is leaked indicating that the presence CoFe2O4. The absorption and the optical band gaps values are increased trend with temperatures also evidence that is enhancing magnetic behavior.