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Effects of chemical fuel composition on energy generation from thermopower waves

Authors
Yeo, TaehanHwang, HayoungJeong, Dong-CheolLee, Kang YeolHong, JongsupSong, ChangsikChoi, Wonjoon
Issue Date
7-11월-2014
Publisher
IOP PUBLISHING LTD
Keywords
thermopower waves; carbon nanotube; chemical fuel; combustion; picric acid; picramide; energy conversion
Citation
NANOTECHNOLOGY, v.25, no.44
Indexed
SCIE
SCOPUS
Journal Title
NANOTECHNOLOGY
Volume
25
Number
44
URI
https://scholar.korea.ac.kr/handle/2021.sw.korea/96788
DOI
10.1088/0957-4484/25/44/445403
ISSN
0957-4484
Abstract
Thermopower waves, which occur during combustion within hybrid structures formed from nanomaterials and chemical fuels, result in a self-propagating thermal reaction and concomitantly generate electrical energy from the acceleration of charge carriers along the nanostructures. The hybrid structures for thermopower waves are composed of two primary components: the core thermoelectric material and the combustible fuel. So far, most studies have focused on investigating various nanomaterials for improving energy generation. Herein, we report that the composition of the chemical fuel used has a significant effect on the power generated by thermopower waves. Hybrid nanostructures consisting of mixtures of picric acid and picramide with sodium azide were synthesized and used to generate thermopower waves. A maximum voltage of similar to 2 V and an average peak specific power as high as 15 kW kg(-1) were obtained using the picric acid/sodium azide/multiwalled carbon nanotubes (MWCNTs) array composite. The average reaction velocity and the output voltage in the case of the picric acid/sodium azide were 25 cm s(-1) and 157 mV, while they were 2 cm s(-1) and 3 mV, in the case of the picramide/sodium azide. These marked differences are attributable to the chemical and structural differences of the mixtures. Mixing picric acid and sodium azide in deionized water resulted in the formation of 2,4,6-trinitro sodium phenoxide and hydrogen azide (H-N-3), owing to the exchange of H+ and Na+ ions, as well as the formation of fiber-like structures, because of benzene p stacking. The negative enthalpy of formation of the new compounds and the fiber-like structures accelerate the reaction and increase the output voltage. Elucidating the effects of the composition of the chemical fuel used in the hybrid nanostructures will allow for the control of the combustion process and help optimize the energy generated from thermopower waves, furthering the development of thermopower waves as an energy source.
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