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Availability and reactivity of N<sub>2</sub>(v) for NH<sub>3</sub> synthesis by plasma catalysis

Brian N. Bayer, Sai Raskar, Igor Adamovich, Peter Bruggeman, Aditya Bhan

2023Plasma Sources Science and Technology22 citationsDOIOpen Access PDF

Abstract

Abstract Production of vibrationally excited N 2 (N 2 ( v )) in atmospheric pressure nonthermal plasma and loss of N 2 ( v ) by gas-phase reactions and reactions on catalytic surfaces are analyzed to examine the role of N 2 ( v ) in NH 3 formation by plasma catalysis. Vibrational state-to-state kinetic models complemented with molecular beam mass spectrometry (MBMS) measurements demonstrate that N 2 ( v &gt; 0) is produced with densities 100× greater than the density of N radicals by a radiofrequency atmospheric pressure plasma jet. The experimentally measured loss of N 2 ( v ) corresponds with a state-to-state kinetic model that describes loss of N 2 ( v ) by surface-mediated vibrational relaxation without consideration of reactions that convert N 2 ( v ) to NH 3 over the catalyst surface. Rate constants for vibrational relaxation of N 2 ( v ) on catalyst surfaces exceed upper bounds on proposed rate constants for NH 3 formation reactions from N 2 ( v ) over Fe when v &lt; 9, Ni when v &lt; 18, and Ag when v &lt; 39, which indicates that only higher vibrational levels can possibly contribute to catalytic NH 3 formation faster than they undergo vibrational relaxation on the surface. Densities of N 2 ( v &gt; 8), vibrational levels that can possibly react over Fe to form NH 3 faster than they undergo vibrational relaxation, are less than or similar to N densities at the inlet of the catalyst bed and measured NH 3 formation for the investigated conditions in this work, while densities of N 2 ( v &gt; 17) and N 2 ( v &gt; 38) are orders of magnitude below the N density at the inlet of the catalyst bed and the measured NH 3 formation. The loss of N 2 ( v ) by vibrational relaxation on the surface limits the ability of N 2 ( v ) to contribute to catalytic NH 3 formation and explains why N 2 ( v ) does not produce NH 3 in quantities that are comparable to NH 3 formation from N even though N 2 ( v &gt; 0) is more abundantly produced by the plasma.

Topics & Concepts

ChemistryCatalysisVibrational energy relaxationReaction rate constantRelaxation (psychology)Kinetic energyReactivity (psychology)Analytical Chemistry (journal)RadicalExcited statePhysical chemistryKineticsAtomic physicsMoleculeOrganic chemistryAlternative medicinePhysicsPsychologySocial psychologyMedicinePathologyQuantum mechanicsPlasma Applications and DiagnosticsCatalytic Processes in Materials ScienceAmmonia Synthesis and Nitrogen Reduction
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