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Title
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Plasma catalysis for ammonia synthesis : a microkinetic modeling study on the contributions of Eley-Rideal reactions
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Author
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Abstract
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| Plasma catalysis is an emerging new technology for the electrification and downscaling of NH3 synthesis. Increasing attention is being paid to the optimization of plasma catalysis with respect to the plasma conditions, the catalyst material, and their mutual interaction. In this work we use microkinetic models to study how the total conversion process is impacted by the combination of different plasma conditions and transition metal catalysts. We study how plasma-generated radicals and vibrationally excited N-2 (present in a dielectric barrier discharge plasma) interact with the catalyst and impact the NH3 turnover frequencies (TOFs). Both filamentary and uniform plasmas are studied, based on plasma chemistry models that provided plasma phase speciation and vibrational distribution functions. The Langmuir-Hinshelwood reaction rate coefficients (i.e., adsorption reactions and subsequent reactions among adsorbates) are determined using conventional scaling relations. An additional set of Eley-Rideal reactions (i.e., direct reactions of plasma radicals with adsorbates) was added and a sensitivity analysis on the assumed reaction rate coefficients was performed. We first show the impact of different vibrational distribution functions on the catalytic dissociation of N-2 and subsequent production of NH3, and we gradually include more radical reactions, to illustrate the contribution of these species and their corresponding reaction pathways. Analysis over a large range of catalysts indicates that different transition metals (metals such as Rh, Ni, Pt, and Pd) optimize the NH(3)TOFs depending on the population of the vibrational levels of N-2. At higher concentrations of plasma-generated radicals, the NH3 TOFs become less dependent on the catalyst material, due to radical adsorptions on the more noble catalysts and Eley-Rideal reactions on the less noble catalysts. |
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Language
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English
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Source (journal)
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ACS Sustainable Chemistry and Engineering. - -
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Publication
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2021
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ISSN
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2168-0485
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DOI
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10.1021/ACSSUSCHEMENG.1C02713
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Volume/pages
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9
(2021)
, p. 13151-13163
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ISI
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000705367800004
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Full text (Publisher's DOI)
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Full text (open access)
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Full text (publisher's version - intranet only)
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