Journal
RSC ADVANCES
Volume 12, Issue 20, Pages 12335-12343Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/d2ra01231f
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Funding
- Natural Sciences and Engineering Research Council of Canada
- Fonds de recherche du Quebec-Nature et technologies, McGill Sustainability Systems Initiative
- Trottier Institute for Sustainability in Engineering and Design
- Vanier Canada Graduate Scholarships
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The reaction rate and hydrogen yield of aluminum particles were highest in high-density supercritical water, possibly due to the increased collision frequency. Decreasing the oxidizer density had minimal effect on hydrogen yield, except in vapor-density water where it significantly dropped.
Aluminum particles, spanning in size from 10 mu m to 3 mm, were reacted with varying densities of water at 655 K. The density of the water is varied from 50 g L-1 to 450 g L-1 in order to understand the effect of density on both reaction rates and yields. Low-density supercritical water is associated with properties that make it an efficient oxidizer: low viscosity, high diffusion, and low relative permittivity. Despite this, it was found that the high-density (450 g L-1) supercritical water was the most efficient oxidizer both in terms of reaction rate and hydrogen yield. The 10 mu m powder had a peak reaction rate of approximately 675 cmH23 min-1 gAl-1 in the high-density water, and a peak reaction rate below 250 cmH23 min-1 gAl-1 in the low- and vapour-density water. A decline in peak reaction rate with decreasing water density was also observed for the 120 mu m powder and the 3 mm slugs. These findings imply that the increased collision frequency, a property of the high-density water, outpaces reduction in the reaction enhancing properties associated with low-density supercritical water. Hydrogen yield was minimally affected by decreasing the oxidizer density from 450 g L-1 to 200 g L-1, but did drop off significantly in the vapour-density (50 g L-1) water.
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