@ARTICLE{Ko_Yun_Taek_Morphology_2021, author={Ko, Yun Taek and Park, Mijeong and Park, Jingyeong and Moon, Jaeyun and Choa, Yong-Ho and Lee, Young-In}, volume={vol. 66}, number={No 3}, journal={Archives of Metallurgy and Materials}, pages={709-712}, howpublished={online}, year={2021}, publisher={Institute of Metallurgy and Materials Science of Polish Academy of Sciences}, publisher={Committee of Materials Engineering and Metallurgy of Polish Academy of Sciences}, abstract={In this study, we demonstrated a method of controllably synthesizing one-dimensional nanostructures having a dense or a hollow structure using fibrous sacrificial templates with tunable crystallinity. The fibrous Ga2O3 templates were prepared by calcining the polymer/gallium precursor nanofiber synthesized by an electrospinning process, and their crystallinity was varied by controlling the calcination temperature from 500oC to 900oC. GaN nanostructures were transformed by nitriding the Ga2O3 nanofibers using NH3 gas. All of the transformed GaN nanostructures maintained a one-dimensional structure well and exhibited a diameter of about 50 nm, but their morphology was clearly distinguished according to the crystallinity of the templates. When the templates having a relatively low crystallinity were used, the transformed GaN showed a hollow nanostructure, and as the crystallinity increased, GaN was converted into a denser nanostructure. This morphological difference can be explained as being caused by the difference in the diffusion rate of Ga depending on the crystallinity of Ga2O3 during the conversion from Ga2O3 to GaN. It is expected that this technique will make possible the tubular nanostructure synthesis of nitride functional nanomaterials.}, type={Article}, title={Morphology Control of One-Dimensional gallium nitride Nanostructures by Modulating the Crystallinity of Sacrificial gallium oxide Templates}, URL={http://ochroma.man.poznan.pl/Content/119239/PDF/AMM-2021-3-08-Young-In%20Lee.pdf}, doi={10.24425/amm.2021.136366}, keywords={GaN, Nanofiber, Nanotube, electrospinning, chemical transformation}, }