Results in Physics (Jan 2016)

Influence of Mn doping on the magnetic and optical properties of ZnO nanocrystalline particles

  • M. Shatnawi,
  • A.M. Alsmadi,
  • I. Bsoul,
  • B. Salameh,
  • M. Mathai,
  • G. Alnawashi,
  • Gassem M. Alzoubi,
  • F. Al-Dweri,
  • M.S. Bawa’aneh

Journal volume & issue
Vol. 6
pp. 1064 – 1071

Abstract

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The structural, optical and magnetic properties of Mn doped ZnO nanocrystalline particles, Zn1-xMnxO, with different percentages of Mn content have been studied. XRD and XPS measurements showed that all samples with Mn doping up to x = 0.1 possess typical wurtzite structure and have no other impurity phases. The incorporation of Mn ions into the ZnO lattice was also confirmed by FTIR and UV–Vis. spectroscopy results. Both XRD and SEM results indicated a slight decrease in the grain size with increasing the Mn doping level. The XPS results indicated an increase in the oxygen vacancies concentration with increasing the Mn doping level. The magnetization measurements revealed a weak ferromagnetic behavior at room temperature and a clear ferromagnetic behavior with relatively large coercive fields at low temperature. The ferromagnetic order is improved by increasing the Mn doping. In addition, we observed an increase in the concentration of oxygen vacancies, which is also induced by increasing the Mn doping level. A ferromagnetic coupling of the local moment of Mn dopants through the sp-d exchange interaction and oxygen vacancies, in addition to different magnetic contributions due to different forms of Mn ions that coexist in the Mn doped nanoparticles were presented in order to interpret the observed magnetic behavior. We observed a clear red shift in the direct band gap and an increase in the coercive field and saturation magnetization values with increasing the Mn doping level. Keywords: ZnO, Mn doped ZnO, Dilute magnetic semiconductors, Magnetic properties, XPS spectroscopy, FTIR, Energy gap, sp-d exchange interaction, Oxygen vacancies