Fe3+-doping on ZnO microstructures via hydrothermal route

  • Kloudene Agrave Salazar National Institute of Physics, University of the Philippines Diliman
  • Verdad Canila Agulto Institute of Laser Engineering, Osaka University
  • Melvin John Fernandez Empizo Institute of Laser Engineering, Osaka University
  • Toshihiko Shimizu Institute of Laser Engineering, Osaka University
  • Kohei Yamanoi Institute of Laser Engineering, Osaka University
  • Keito Shinohara Institute of Laser Engineering, Osaka University
  • Pinit Kidkhunthod Synchrotron Light Research Institute
  • Suchinda Sattayaporn Synchrotron Light Research Institute
  • Vallerie Ann Samson National Institute of Physics, University of the Philippines Diliman
  • Nobuhiko Sarukura Institute of Laser Engineering, Osaka University
  • Roland V Sarmago National Institute of Physics, University of the Philippines Diliman

Abstract

Zinc oxide microrods were fabricated hydrothermally with Fe3+ inclusions. The incorporation of Fe in the rods as interstitials were verified using Xray Absorption Near Edge Spectroscopy (XANES), as opposed to a zinc or oxygen substitution which requires lower coordination for Fe. The interstitial incorporation is further evidenced by the unchanged ZnO lattice parameters and crystal habit.

Published
2019-05-19
How to Cite
[1]
K. Salazar, V. Agulto, M. J. Empizo, T. Shimizu, K. Yamanoi, K. Shinohara, P. Kidkhunthod, S. Sattayaporn, V. A. Samson, N. Sarukura, and R. Sarmago. Fe3+-doping on ZnO microstructures via hydrothermal route, Proceedings of the Samahang Pisika ng Pilipinas 37, SPP-2019-1E-04 (2019). URL: https://paperview.spp-online.org/proceedings/article/view/SPP-2019-1E-04.
Section
Condensed Matter and Materials Science