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Impact of shock waves on the physical and chemical properties of aligned zinc oxide structures grown over metal-sheets

Title
Impact of shock waves on the physical and chemical properties of aligned zinc oxide structures grown over metal-sheets
Author(s)
Lingandhinne, R.M.R.Mudusu, D.Nandanapalli, Koteeswara ReddyReddy, K.P.J.Lee, S.
Issued Date
2022-06
Citation
Materials Today Chemistry, v.24
Type
Article
Author Keywords
Nanostructured zinc oxide (ZnO)Space engineering applicationsThermal stabilityFlexible sheetsChemical growth
Keywords
HYDROTHERMAL SYNTHESISZNO NANOSTRUCTURESSPACEPERFORMANCENANOMATERIALSAEROSPACEDYE
ISSN
2468-5194
Abstract
Zinc oxide (ZnO) nanorods were developed on stainless steel (SS) sheets as well as glass substrates in two steps by adopting well-established two different chemical methods namely, spray pyrolysis and chemical bath deposition techniques. Then, the structures were exposed to dynamically generated shock waves in a home-built shock tunnel. All the as-grown and shock waves exposed structures were characterized with advanced analytical techniques. Surface morphology and structural studies reveal that the as-grown nanostructured films over the both SS and glass substrates possess nanorods-like surface morphology; however, they exhibited (101) and (001) orientations as predominant orientations, respectively. From micro Raman analysis, it is noticed that the nanorod structures grown on both surfaces have good phase purity and crystalline quality. On the other hand, the cathodoluminescence studies show that these hydrothermally grown ZnO nanorods possess a large number of native defects. Finally, the ZnO nanorods exposed to shock waves generated with a temperature and pressure of ca. ∼20,000 K and ∼6 MPa for a short duration of 2–3 ms exhibited superb sustainability in terms of surface morphology as well as crystalline quality, which is mainly attributed to the slantly overlapped morphology as well as the high melting temperature of ZnO nanorods. © 2022 Elsevier Ltd
URI
http://hdl.handle.net/20.500.11750/16932
DOI
10.1016/j.mtchem.2022.100921
Publisher
Elsevier
Related Researcher
  • 이성원 Lee, Sungwon
  • Research Interests Ultrathin Device Fabrication; Bio sensors Development; Functional Material Development
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Department of Physics and Chemistry Bio-Harmonized Device Lab 1. Journal Articles

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