Use of metallic Ni for H 2 production in S–I thermochemical cycle: Experimental and theoretical analysis

Use of metallic Ni for H 2 production in S–I thermochemical cycle: Experimental and theoretical analysis

The gaseous hydrogen iodide decomposition is a thermodynamically limited reaction and subsequently a considerable energy expense for the separation and recirculation of the unreacted species is required. In addition the homogeneous gas phase decomposition of hydrogen iodide has a very low rate and t...

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Bibliographic Details
Published in:International journal of hydrogen energy Vol. 34; no. 3; pp. 1200 - 1207
Main Authors: Lanchi, M., Caputo, G., Liberatore, R., Marrelli, L., Sau, S., Spadoni, A., Tarquini, P.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-02-2009
Subjects:
Alternative process
Hydriodic acid decomposition section
Hydrogen production
Nickel iodide
Nickel salt
Sulphur–Iodine cycle
Thermochemical cycles
Thermochemical cycles
Hydriodic acid decomposition section
Sulphur–Iodine cycle
Nickel salt
Nickel iodide
Hydrogen production
Alternative process
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Summary:The gaseous hydrogen iodide decomposition is a thermodynamically limited reaction and subsequently a considerable energy expense for the separation and recirculation of the unreacted species is required. In addition the homogeneous gas phase decomposition of hydrogen iodide has a very low rate and the use of a catalytic system, which is generally highly expensive, is necessary. Hence, with the aim of overcoming the bottleneck represented by the hydrogen releasing step of the Sulphur–Iodine (S–I) cycle in terms of costs and process efficiency, in the present work an alternative version of the HI decomposition section (HI x section) is proposed. In that alternative configuration the addition of metallic nickel into the heavy phase coming from Bunsen reaction is conceived in order to quantitatively obtain hydrogen at low temperature. A theoretical and experimental investigation has been performed, a new cycle has been conceived and the resulting energy demand assessed.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2008.10.044