Phase Transformations of Cobalt Oxides in CoxOy-ZnO Multipod Nanostructures via Combustion from Thermopower Waves

The study of combustion at the interfaces of materials and chemical fuels has led to developments in diverse fields such as materials chemistry and energy conversion. Recently, it has been suggested that thermopower waves can utilize chemical‐thermal‐electrical‐energy conversion in hybrid structures...

Full description

Saved in:
Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2015-09, Vol.11 (36), p.4762-4773
Main Authors: Lee, Kang Yeol, Hwang, Hayoung, Choi, Wonjoon
Format: Article
Language:English
Subjects:
Co oxide phase transformation
combustion
energy conversion
Nanotechnology
Photovoltaic cells
thermopower waves
Zn oxide
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The study of combustion at the interfaces of materials and chemical fuels has led to developments in diverse fields such as materials chemistry and energy conversion. Recently, it has been suggested that thermopower waves can utilize chemical‐thermal‐electrical‐energy conversion in hybrid structures comprising nanomaterials and combustible fuels to produce enhanced combustion waves with concomitant voltage generation. In this study, this is the first time that the direct phase transformation of Co‐doped ZnO via instant combustion waves and its applications to thermopower waves is presented. It is demonstrated that the chemical combustion waves at the surfaces of Co3O4–ZnO multipod nanostructures (deep brown in color) enable direct phase transformations to newly formed CoO–ZnO1−x nanoparticles (olive green in color). The oxygen molecules are released from Co3O4–ZnO to CoO–ZnO1−x under high‐temperature conditions in the reaction front regime in combustion, whereas the CoO–ZnO multipod nanoparticles do not undergo any transformations and thus do not experience any color change. This oxygen‐release mechanism is applicable to thermopower waves, enhances the self‐propagating combustion velocity, and forms lattice defects that interrupt the charge‐carrier movements inside the nanostructures. The chemical transformation and corresponding energy transport observed in this study can contribute to diverse potential applications, including direct‐combustion synthesis and energy conversion. The chemical combustion waves at the surfaces of Co3O4–ZnO multipod nanostructures (deep brown) enable direct phase transformations to newly formed CoO–ZnO1−x nanoparticles (olive green). The oxygen molecules are released from Co3O4–ZnO to CoO–ZnO1−x under high temperature in the reaction front regime in combustion, and this direct phase transformation is applicable to thermopower waves, as well as the direct chemical synthesis.
ISSN:1613-6810
1613-6829
DOI:10.1002/smll.201501038