The dissociation of carbon dioxide at high temperatures

The power of an internal combustion engine is greatest when operating with a “rich” mixture, that is to say, with a mixture which contains more fuel than is necessary for complete combustion. Similarly, it is found that if mixtures of carbon monoxide and air in varying proportions are exploded in a...

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Bibliographic Details
Published in:Proceedings of the Royal Society of London. Series A, Containing papers of a mathematical and physical character Containing papers of a mathematical and physical character, 1927-07, Vol.115 (771), p.318-333
Main Authors: Fenning, R. W., Tizard, Henry Thomas
Format: Article
Language:English
Subjects:
Air pressure
Carbon dioxide
Carbon monoxide
Combustion temperature
Explosions
High temperature
Nitrogen
Oxygen
Specific heat
Water vapor
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Summary:The power of an internal combustion engine is greatest when operating with a “rich” mixture, that is to say, with a mixture which contains more fuel than is necessary for complete combustion. Similarly, it is found that if mixtures of carbon monoxide and air in varying proportions are exploded in a closed bomb at constant initial temperature and pressure, the explosion pressure is greatest when the ratio CO/O2 is greater than 2. These phenomena are known to be connected with the dissociation of carbon dioxide at high temperatures, for if there were no dissociation we should expect the explosion pressure to be greatest when CO/O2 = 2. No attention appears, however, to have been paid to the position of the maximum. It can be shown in the following way that there is a very simple relation between the composition of the mixture giving maximum pressure on explosion, and the dissociation of carbon dioxide at the maximum explosion temperature. Let the initial composition be represented by the expression 2 (1 + a) CO + O2 + b N2 (Total mols = 3 + 2a + b), and let Pi, Ti represent the initial pressure and temperature; Pe the maximum pressure observed after explosion, and Te the corresponding maximum temperature.
ISSN:0950-1207
2053-9150
DOI:10.1098/rspa.1927.0095