Ammonium chloride-metal hydride based reaction cycle for vehicular applications

Ammonium chloride-metal hydride based reaction cycle for vehicular applications

© 2019 The Royal Society of Chemistry. Hydrogen and ammonia have attracted attention as potential energy vectors due to their abundance and minimal environmental impact when used as a fuel source. To be a commercially viable alternative to fossil fuels, gaseous fuel sources must adhere to a w...

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Bibliographic Details
Main Authors: Stewart, Helen, Humphries, Terry, Sheppard, Drew, Tortoza, Mariana, Sofianos, M. Veronica, Liu, Shaomin, Buckley, Craig
Format: Journal Article
Language:English
Published: ROYAL SOC CHEMISTRY 2019
Subjects:
Science & Technology
Physical Sciences
Technology
Chemistry, Physical
Energy & Fuels
Materials Science, Multidisciplinary
Chemistry
Materials Science
HYDROGEN-STORAGE
THERMAL-DECOMPOSITION
CRYSTAL-STRUCTURES
COMPLEX HYDRIDES
ENERGY
DIFFRACTION
COMPOSITES
COMBUSTION
TRANSITION
EXPANSION
Online Access:http://purl.org/au-research/grants/arc/LE0989180
http://hdl.handle.net/20.500.11937/82095
Description
Summary:© 2019 The Royal Society of Chemistry. Hydrogen and ammonia have attracted attention as potential energy vectors due to their abundance and minimal environmental impact when used as a fuel source. To be a commercially viable alternative to fossil fuels, gaseous fuel sources must adhere to a wide range of standards specifying hydrogen delivery temperature, gravimetric capacity and cost. In this article, an ammonium chloride-metal hydride reaction cycle that enables the solid thermal decomposition products to be recycled using industrial processes is proposed. A range of metal hydrides and metal amides were reacted with ammonium chloride to determine the reaction pathways, products and overall feasibility of the cycle. The NH 4 Cl-MH (MH = metal hydride) and NH 4 Cl-MNH 2 (MNH 2 = metal amide) mixtures were heated to temperatures of up to 500 °C. The resulting products were experimentally characterised using temperature program desorption residual gas analysis, simultaneous differential scanning calorimetry and thermogravimetric analysis and in situ powder X-ray diffraction. Similar analysis was undertaken to determine the effect of catalyst addition to the starting materials. A maximum yield of 41 wt% of hydrogen and ammonia gas mixtures were released from the NH 4 Cl-MH materials at a maximum yield of 41 wt%. This exceptional gravimetric capacity allows for volumetric gas densities (363-657 kg m -3 ) that are much higher than pure NH 3 , H 2 or metal hydride materials. Overall, this reaction cycle allows carbon-neutral regeneration of the starting materials, making it a potential sustainable energy option.

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