Best practices in Quantum Monte Carlo for metal catalysis: CO hydrolysis on Pt(111)

Hydrogen production as a clean, sustainable replacement for fossil fuels is gathering pace. Research work and prototyping various aspects of hydrogen power is now a priority. Over 90 \% of all chemical manufacture uses a solid catalyst. This work describes catalytic selective hydrogen production optimising reactant structure on a model catalyst. Focus is on O-H bond dissociation in format radicals formed after carbon-monoxide is co-adsorbed with water at Pt(111). Finally, hydrogen gas is given off. Many chemical reactions involve bond-dissociation. This process is often the key to rate-limiting reaction steps at solid surfaces. %This is also true for reactions at solid surfaces, in which the dissociation step is often limiting but facilitated in comparison to gas phase reaction channels. Since bond-breaking is poorly described by Hartree-Fock and DFT methods, our embedded active site approach is used. This work demonstrates Quantum Monte Carlo (QMC) methodology using a very simple four primitive-cell layer model, oriented to expose Pt (111). QMC is a stochastic approach to solving the Schr{\"o}dinger equation recently came of age for heterogeneous systems involving solids. During hydrolysis of carbon monoxide, initial O-H bond stretch is rate-limiting. This dissociation energy is offset by Pt-H bond formation at the surface. The reactive formate (H-O-C=O) species formed, by initial hydrolysis of CO, also interact with a vicinal Pt. These are subsequently desorbed. They then produce carbon dioxide and hydrogen, with a H-atom dissociated from the formate species and another desorbed at the Pt(111) face. Our approach allows a high-level configuration interaction (CI) wave-function to be used, expanded in plane-waves and embedded in the metal lattice exposing its close-packed face. The resulting periodic function is used to guide the QMC calculation.