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Ammonia cracking for hydrogen production using a microwave argon plasma jet

Xinhua Zhang, Min Suk

2023Journal of Physics D Applied Physics20 citationsDOIOpen Access PDF

Abstract

Abstract Ammonia (NH 3 ) is a promising hydrogen carrier that effectively connects producers of blue hydrogen with consumers, giving rapid conversion of ammonia to hydrogen a critical role in utilizing hydrogen at the endpoints of application in an ammonia-hydrogen economy. Because conventional thermal cracking of NH 3 is an energy intensive process, requiring a relatively longer cold start duration, plasma technology is being considered as an assisting tool—or an alternative. Here we detail how an NH 3 cracking process, using a microwave plasma jet (MWPJ) under atmospheric pressure, was governed by thermal decomposition reactions. We found that a delivered MW energy density (ED) captured the conversion of NH 3 well, showing a full conversion for ED > 6 kJ l −1 with 0.5-% v/v NH 3 in an argon flow. The hydrogen production rate displayed a linear increase with MW power and the NH 3 content, being almost independent of a total flow rate. A simplified one-dimensional numerical model, adopting a thermal NH 3 decomposition mechanism, predicted the experimental data well, indicating the importance of thermal decomposition in the plasma chemistry. We believe that such a prompt thermal reaction, caused by MW plasma, will facilitate a mobile and/or non-steady application. A process combined with the conventional catalytic method should also effectively solve a cold start issue.

Topics & Concepts

HydrogenHydrogen productionAmmoniaChemistryArgonCrackingThermal decompositionJet (fluid)PlasmaDecompositionAnalytical Chemistry (journal)ThermodynamicsPhysical chemistryOrganic chemistryPhysicsNuclear physicsAmmonia Synthesis and Nitrogen Reduction
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