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Catalytic resonance of ammonia synthesis by simulated dynamic ruthenium crystal strain

Gerhard R. Wittreich, Shizhong Liu, Paul J. Dauenhauer, Dionisios G. Vlachos

2022Science Advances82 citationsDOIOpen Access PDF

Abstract

Ammonia affords dense storage for renewable energy as a fungible liquid fuel, provided it can be efficiently synthesized from hydrogen and nitrogen. In this work, the catalysis of ammonia synthesis was computationally explored beyond the Sabatier limit by dynamically straining a ruthenium crystal (±4%) at the resonant frequencies (10 2 to 10 5+ Hz) of N 2 surface dissociation and hydrogenation. Density functional theory calculations at different strain conditions indicated that the energies of NH x surface intermediates and transition states scale linearly, allowing the description of ammonia synthesis at a continuum of strain conditions. A microkinetic model including multiple sites and surface diffusion between step and Ru(0001) terrace sites of varying ratios for nanoparticles of differing size revealed that dynamic strain yields catalytic ammonia synthesis conversion and turnover frequency comparable to industrial reactors (400°C, 200 atm) but at lower temperature (320°C) and an order of magnitude lower pressure (20 atm).

Topics & Concepts

Ammonia productionCatalysisRutheniumAmmoniaDissociation (chemistry)Chemical physicsHydrogenMaterials scienceChemistryStrain (injury)Chemical engineeringNanoparticleInorganic chemistryPhysical chemistryNanotechnologyOrganic chemistryEngineeringMedicineInternal medicineAmmonia Synthesis and Nitrogen ReductionHydrogen Storage and MaterialsAdvanced Photocatalysis Techniques
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