Redox transformations of Ru catalyst during NO oxidation at industrial nitric acid production conditions

Oxidation of nitric oxide is one of the main steps in the Ostwald process for industrial nitric acid production. This work summarises the use of gamma-Al2O3 supported Ru catalyst to study the oxidation of NO to NO2 at ambient and 4 bar pressure with a feed of 10% NO, 6% O-2, 15% H2O, and rest Ar. The catalyst was synthesised using wet impregnation and characterised by BET, CO chemisorption, H-2-TPR, XPS, XRD, in-situ XAS-XRD and DRIFTS. We report the activity and kinetics of supported ruthenium catalyst for NO oxidation under realistic nitric acid plant conditions. The catalyst exhibited a promising low-temperature activity of 72% at 340 degrees C in complete nitric acid condition and 37% at 420 degrees C in partial nitric acid condition. An apparent activation energy of 152 kJ/mol was observed and the overall rate was determined to be r = k(f) center dot K-G center dot P-NO(2) center dot P-O2/P-NO(2), where k(f) and K-G represents forward rate and equilibrium rate constants respectively. The reaction was found to be second order with respect to NO, first order with respect to O-2 and inversely dependent on NO2 partial pressure. The stability of the catalyst was also tested during 45 h of isothermal NO oxidation at ambient pressure. From in-situ XAS-XRD and DRIFTS experiments it was revealed that during isothermal NO oxidation the reaction oscillates as the ruthenium surface goes through redox cycles. A plausible reaction mechanism that fits with our experimental observations and the oxidative nature of ruthenium is proposed. This study demonstrates and explains the capacity of supported ruthenium catalysts to oxidise NO to NO2 in industrial nitric acid production conditions.

Automated summary

This study summarizes the use of a gamma-Al2O3 supported Ru catalyst for the oxidation of NO to NO2 in industrial nitric acid production. The catalyst exhibited high activity and kinetic parameters under nitric acid plant conditions, and the apparent activation energy and reaction mechanism were investigated.