Abstract
ZnO nanorods were grown on a zinc substrate via cathodic delamination of a polymer coating, a tailored corrosion process, at room temperature. A comparison between in situ Raman spectra and post mortem cross sectional analysis by Raman spectroscopy, photoluminescence spectroscopy and scanning electron microscopy shows that in the initial stages of the synthesis, preferentially defect rich ZnO grows. At later stages, crystalline wurtzite ZnO growth dominates. The result is nanorod arrays consisting of nanorods with a large density of point defects in the ≈500 nm range near the zinc substrate, and low defect density in the regions further away from the interface. The growth, which proceeds over several hours, can be interrupted at any time. Large salt concentrations in the corrosive medium increase the growth rate, but also the amount of point defects. The resulting rods show strongly position-dependent luminescence and Raman spectra. Different luminescence can thus be selectively excited, based on the position of excitation.
Highlights
Conceptual insightsZnO nanorods have been suggested for a number of applications, because of their chemical properties, their optoelectronic properties, and their piezoelectricity
Well-aligned nanorods form in the later stages of growth
The growth of nanorods stops due to depletion in the concentration of dissolved zinc species
Summary
Conceptual insightsZnO nanorods have been suggested for a number of applications, because of their chemical properties, their optoelectronic properties, and their piezoelectricity. This work shows that by using the corrosion process of cathodic delamination of a polymer coating from zinc, rods can be produced with different defect densities at both ends. These ‘‘Janus’’ type rods show different luminescence and Raman spectra at both ends. The synthesis can be monitored in situ and interrupted to produce rods of different lengths and optical properties. These particles show that the optical and electronic properties can be different in a single particle, produced by a scalable method
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