| Literature DB >> 32701180 |
Fernando Garcia-Martinez1, Carlos García-Fernández1, Juan Pablo Simonovis2, Adrian Hunt2, Andrew Walter2, Iradwikanari Waluyo2, Florian Bertram3, Lindsay R Merte3, Mikhail Shipilin3, Sebastian Pfaff3, Sara Blomberg4, Johan Zetterberg3, Johan Gustafson3, Edvin Lundgren3, Daniel Sánchez-Portal1, Frederik Schiller1, J Enrique Ortega1,5,6.
Abstract
The catalytic oxidation of CO on transition metals, such as Pt, is commonly viewed as a sharp transition from the CO-inhibited surface to the active metal, covered with O. However, we find that minor amounts of O are present in the CO-poisoned layer that explain why, surprisingly, CO desorbs at stepped and flat Pt crystal planes at once, regardless of the reaction conditions. Using near-ambient pressure X-ray photoemission and a curved Pt(111) crystal we probe the chemical composition at surfaces with variable step density during the CO oxidation reaction. Analysis of C and O core levels across the curved crystal reveals that, right before light-off, subsurface O builds up within (111) terraces. This is key to trigger the simultaneous ignition of the catalytic reaction at different Pt surfaces: a CO-Pt-O complex is formed that equals the CO chemisorption energy at terraces and steps, leading to the abrupt desorption of poisoning CO from all crystal facets at the same temperature.Entities:
Keywords: CO oxidation; curved surfaces; ignition; near-ambient pressure photoemission; subsurface oxygen
Year: 2020 PMID: 32701180 DOI: 10.1002/anie.202007195
Source DB: PubMed Journal: Angew Chem Int Ed Engl ISSN: 1433-7851 Impact factor: 15.336