Doped Magnetic ZnO p-n Junction Heterostructures for Nano-Spintronic Devices

In the course of this project we carried out a detailed structural and functional characterisation of doped ZnO nanowires synthesised within polycabonate templates via a direct electrodeposition technique. The composition and structure of the nanowires were investigated using transmission electron microscopy (TEM), X-ray diffraction (XRD), extended x-ray absorption fine structure (EXAFS) and x-ray absorption near edge structure (XANES). The magnetic properties of the systems were studied using a superconducting quantum interference device (SQUID) magnetometry.
In the case of transition metal doped ZnO nanowires such Co-doped ZnO nanowires it was observed that although the nanowires are polycrystalline in nature they are highly textured and have both single crystal and polycrystalline regions. Using TEM and corresponding elemental detection methods it was also observed that there were no detectable variation in the composition between the different regions of the nanowire
EXAFS and XANES measurements the absence of secondary phases such as ZnCo alloys or Co nanoclusters and proved that Co is fully incorporated into the lattice
Magnetic measurements confirmed the presence of a magnetically ordered phase at T<350 K, which is attributed to dilute Co2+ ions in the ZnO nanowires.
Co-doping with Ag+ or Cu+ to produce p-type material was achieved by simple bath modification; Ag-doping resulted in the formation of a black film due to the generation of colour centres in the material; this effect is still being investigated at the host institution.
In this project have used a simple low-cost, low temperature electrodeposition process to synthesise doped ZnO nanowires with ordered architectures. A thorough characterisation of these 1-d nanostructured arrays has helped us develop a better fundamental understanding of the relationship between structure and functional properties of these materials which are potential candidates for use in future functional electronic devices.