Manipulation Over Phase Transformation in Iron Oxide Nanoparticles via Calcination Temperature and Their Effect on Magnetic and Dielectric Properties

Iron oxide nanoparticles (IONPs) have gained technological importance in many fields that broadly includes health, environment, and energy applications. Consequently, the synthesis of IONPs with different phases and morphologies possesses significant interest. Therefore, here we report the facile synthesis of IONPs through the hydrothermal method followed by calcination process at different temperatures (300 degrees C, 500 degrees C, and 700 degrees C) and studied the influence of various phases of IONPs on their magnetic and dielectric properties. The structural studies using X-ray diffraction confirmed that the as-prepared material possesses the Fe3O4 phase, and the increasing calcination temperatures leads to the phase transformation from maghemite (gamma-Fe2O3) to hematite (alpha-Fe2O3) phase. The morphological studies revealed that the as-prepared material possesses flaky morphology with a size around 20 nm,gamma-Fe2O3 to have nanoparticles of sizes around 50 nm, and a-Fe2O3 phase with mixed morphology of hexagonal and elongated shaped particles with size ranges from 60-140 nm. The optical properties of synthesized materials revealed that the band gap energy is found to be varied in between 2 and 2.7 eV depending upon the phase of IONPs. The hysteresis behavior of as-prepared and calcined IONPs at 300 degrees C and 500 degrees C indicated the soft-ferromagnetic properties of the phases. However, the IONPs prepared at 700 degrees showed the weak-ferromagnetic property due to the existence of mixed a-Fe2O3 phase. All the calcined IONPs showed the soft-ferromagnetic properties with saturation magnetization (M-s) that varied in between 47.88 and 0.35 emu/g. The occurrence of the reduced Ms ascribed to the phase transformation of the respective IONPs system. The dielectric studies of IONPs exhibited drastic variations with increasing frequency and with respect to their phase.