Structural, optical and magnetic properties of α- and β-MnO2 nanorods

Abstract

Herein, we synthesise various polymorphs of MnO2 through hydrothermal technique. Formation of pure tetragonal structured α-, β- and mixture of α and β phase of MnO2are identified through Fourier transform infrared spectroscopy (FTIR) and X-Ray diffraction (XRD).Rietveld refinement reviles 73% of α-MnO2 and 27% of β-MnO2 present in αβ-MnO2. From Field emission scanning electron micrographs (FESEM), average diameter of α- and β-MnO2nanorods is found to be 36 nm and 23 nm, respectively, while in αβ-MnO2, nanorods of two different sizes, 28 and 116 nm are observed. Among all polymorphs, small size of nanorods in β-MnO2 results high specific capacitance. Through UV–visible absorption spectra, the optical band gap of α-, β- and αβ-MnO2nanorods are estimated to be 1.53, 1.30 and 1.45 eV, respectively. XPS confirms the presence of large concentration of Mn3+ in α- and αβ-MnO2 nanorods results high effective magnetic moment in comparison to the theoretical one which is almost same in β-MnO2. Henceforth, we evaluate the accurate composition of MnO2 as α-MnO1.48, β-MnO1.86 and αβ-MnO1.15. Spin-glass/cluster-glass behavior is confirmed from ac susceptibility and remanent magnetization measurements in β-MnO2and αβ-MnO2which is absent in α-MnO2 depending on a critical concentration of Mn3+ions.