Issue 5, 2012

Seeded growth induced amorphous to crystalline transformation of niobium oxide nanostructures

Abstract

A novel high-temperature synthesis of niobium oxide nanostructures has been developed through an amorphous intermediate that crystallizes into anisotropic crystalline structures through a complex mechanism of nucleation–dissolution–selective growth induced by seeded growth. The amorphous materials formed by the thermolysis of niobium oleate transformed into crystalline platelets, wires or bundled wires after the injection of additional niobium oleate at different temperatures. The temperature of the solution during injection of the additional precursor determined the morphology of the formed crystalline structure. The time- and temperature-dependent evolution of the niobium oxide nanostructures demonstrates that amorphous materials progressively turned to crystalline materials. We tuned the size of wires and platelets by the consecutive injection of the precursor solution into the reaction mixture under isothermal conditions. With the sequential injection of the precursor solution, we demonstrate that the anisotropic growth of individual nanowires occurs exclusively along the ends, without the formation of any new nuclei. A mechanism for the transformation of well-defined platelets from wires has been proposed and is due to the exclusive loss of mass at the ends of the wires while growth of the platelets initially occurs along the (001) direction which is then replaced by the (110) face.

Graphical abstract: Seeded growth induced amorphous to crystalline transformation of niobium oxide nanostructures

Supplementary files

Article information

Article type
Paper
Submitted
20 Nov 2011
Accepted
29 Dec 2011
First published
12 Jan 2012

Nanoscale, 2012,4, 1782-1788

Seeded growth induced amorphous to crystalline transformation of niobium oxide nanostructures

S. Jana and R. M. Rioux, Nanoscale, 2012, 4, 1782 DOI: 10.1039/C2NR11803C

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