Revolutionizing Ammonia Synthesis: FeCoNiAlSi High-Entropy Alloy Catalyst for Low-Pressure, Low-Temperature Applications

Creators: Shen, Yidi^{1, 2}; Sementa, Luca³; Johnson, Duane D.¹; Fortunelli, Alessandro²; An, Qi¹; Goddard, William A.²

1. Iowa State University
2. California Institute of Technology
3. National Research Council

Abstract

The Haber-Bosch (HB) process, critical for global ammonia production, is hindered by its high energy consumption and operational demands, requiring extreme pressures and temperatures. Developing catalysts that reduce these demands while maintaining practical efficiency is essential for achieving sustainable ammonia synthesis. Here, we investigate the FeCoNi(AlSi)_0.76 high-entropy alloy (HEA) as a catalyst for the HB process using quantum mechanics (QM) and kinetic Monte Carlo (kMC) simulations. Mechanistic analysis revealed significantly lower reaction barriers compared to pure Fe, and kMC simulations predict an NH₃ turnover frequency (TOF) that is 65 times higher than pure Fe under industrial conditions. Under reduced pressure (21 atm) and moderate temperature condition (673 K), the HEA retained half the NH₃ production rate of pure Fe at extreme industrial conditions, revealing its potential to reduce energy and pressure requirements. This study demonstrates the promise of HEAs in enabling more energy-efficient and sustainable ammonia production technologies.

Copyright and License (English)

Acknowledgement (English)

Y.S. and Q.A. received support from ISU startup research grant. A.F. and W.A.G. received support from NSF (CBET-1805022, CBET-2005250, and CBET-2311117). A.F. and L.S. are grateful to the Italian CINECA supercomputing center for providing computational resources within the ISCRA program, and acknowledge financial support from the Italian Ministry of Environment and Energy Security POR H2 AdP MMES/ENEA project “Research and development on hydrogen”.

Supplemental Material (English)

The supporting information : The energy lists include the formation energy of 1N, 2N, 3N, 4N based on the bare surface and N₂ gas phase, the formation energy of 3N·NH, 3N·NH₂, 3N·NH₃ based on 4N state and H₂ gas phase, and the NH₃ desorption/adsorption energy based on the 3N, the 3N·NH₃ state, and NH₃ gas phase (PDF)

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