| AVS 65th International Symposium & Exhibition | |
| Surface Science Division | Monday Sessions |
| Session SS+HC-MoA |
| Session: | Theory and Modeling of Surfaces and Reactions |
| Presenter: | Jean-Sabin McEwen, Washington State University |
| Authors: | A.J.R. Hensley, Washington State University A.J. Therrien, Tufts University R. Zhang, Washington State University A.C. Schilling, Tufts University K. Groden, Washington State University E.C.H. Sykes, Tufts University J.-S. McEwen, Washington State University |
| Correspondent: | Click to Email |
Automotive catalysis is more complicated than most applications of catalysts, because of the complex and dynamic changes in the exhaust gas environment. The ability to create highly dispersed, single-site catalysts, which are highly efficient and have low cost, is very much desirable [1]. While single atom sites can be created, there is still disagreement over whether the single atom sites are indeed catalytically active or if the observed catalytic activity of single-site catalysts is due to metal nanoparticles either unobserved during initial microscopy studies or formed upon exposure to catalytic conditions [2]. Such disagreements create a crucial need for the development of well-defined single-site catalysts with an accurate theoretical model in order to correctly determine the chemical nature of the catalytically active sites. To this end, we have studied low-temperature CO oxidation on Pt single-site catalysts supported on the “29” Cu surface oxide. The “29” Cu surface oxide is a high coverage chiral structure. Through the use of scanning tunneling microscopy (STM), CO temperature programmed desorption (TPD), and density functional theory (DFT) techniques, we determined that an accurate model for the “29” Cu oxide surface is formed from the growth of a CuxO layer formed from 6 fused hexagonal rings above the Cu (111) surface where 5 oxygen adatoms are added at the center of the CuxO rings [3, 4]. Furthermore, the state of the Pt single atoms before, during, and after reaction is determined through a combination of theoretical and experimental techniques. It is found that the Pt dosed to the “29” Cu oxide surface forms well dispersed single atom sites which are metallic in nature [5]. During catalysis, CO2 forms from the combination of an oxygen from the “29” Cu oxide surface with the CO adsorbed on the Pt single atoms.
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3. Therrien, A.J., R. Zhang, F.R. Lucci, M.D. Marcinkowski, A.J.R. Hensley, J.-S. McEwen, and E.C.H. Sykes, Journal of Physical Chemistry C, 2016. 120: p. 10879-10886.
4. Hensley, A.J.R., A.J. Therrien, R. Zhang, M.D. Marcinkowski, F.R. Lucci, E.C.H. Sykes, and J.-S. McEwen, Journal of Physical Chemistry C, 2016. 120: p. 25387-25394.
5. Therrien, A.J., A.J.R. Hensley, M.D. Marcinkowski, R. Zhang, F.R. Lucci, B. Coughlin, A.C. Schilling, J.-S. McEwen, and E.C.H. Sykes, Nature Catalysis, 2018. 1: p. 192-198.