Renewable hydrogen from nonvolatile fuels by reactive flash volatilization

J. R. Salge; B. J. Dreyer; P. J. Dauenhauer; L. D. Schmidt

doi:10.1126/science.1131244

Renewable hydrogen from nonvolatile fuels by reactive flash volatilization

J. R. Salge, B. J. Dreyer, P. J. Dauenhauer, L. D. Schmidt

Chemical Engineering and Materials Science

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86 Scopus citations

Abstract

Droplets of nonvolatile fuels such as soy oil and glucose-water solutions can be flash evaporated by catalytic partial oxidation to produce hydrogen in high yields with a total time in the reactor of less than 50 milliseconds. Pyrolysis, coupled with catalytic oxidation of the fuels and their fragments upon impact with a hot rhodium-cerium catalyst surface, avoids the formation of deactivating carbon layers on the catalyst. The catalytic reactions of these products generate approximately 1 megawatt of heat per square meter, which maintains the catalyst surface above 800°C at high drop impact rates. At these temperatures, heavy fuels can be catalytically transformed directly into hydrogen, carbon monoxide, and other small molecules in very short contact times without the formation of carbon.

Original language	English (US)
Pages (from-to)	801-804
Number of pages	4
Journal	Science
Volume	314
Issue number	5800
DOIs	https://doi.org/10.1126/science.1131244
State	Published - Nov 3 2006

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abstract = "Droplets of nonvolatile fuels such as soy oil and glucose-water solutions can be flash evaporated by catalytic partial oxidation to produce hydrogen in high yields with a total time in the reactor of less than 50 milliseconds. Pyrolysis, coupled with catalytic oxidation of the fuels and their fragments upon impact with a hot rhodium-cerium catalyst surface, avoids the formation of deactivating carbon layers on the catalyst. The catalytic reactions of these products generate approximately 1 megawatt of heat per square meter, which maintains the catalyst surface above 800°C at high drop impact rates. At these temperatures, heavy fuels can be catalytically transformed directly into hydrogen, carbon monoxide, and other small molecules in very short contact times without the formation of carbon.",

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AU - Dreyer, B. J.

AU - Dauenhauer, P. J.

AU - Schmidt, L. D.

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AB - Droplets of nonvolatile fuels such as soy oil and glucose-water solutions can be flash evaporated by catalytic partial oxidation to produce hydrogen in high yields with a total time in the reactor of less than 50 milliseconds. Pyrolysis, coupled with catalytic oxidation of the fuels and their fragments upon impact with a hot rhodium-cerium catalyst surface, avoids the formation of deactivating carbon layers on the catalyst. The catalytic reactions of these products generate approximately 1 megawatt of heat per square meter, which maintains the catalyst surface above 800°C at high drop impact rates. At these temperatures, heavy fuels can be catalytically transformed directly into hydrogen, carbon monoxide, and other small molecules in very short contact times without the formation of carbon.

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Renewable hydrogen from nonvolatile fuels by reactive flash volatilization

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