Water and Hydroxyl Reactivity on Flat and Stepped Cobalt Surfaces

Weststrate, C.J.; Sharma, Devyani; Gleeson, M.A.; Niemantsverdriet, J.W.

doi:10.1021/acs.jpcc.2c08425

Cited by 4 publications

(3 citation statements)

References 34 publications

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“…The reference spectrum for a mixed CO ad −O ad layer was obtained by dosing CO at 300 K onto the O-covered sample, while the reference spectrum for OH ad was obtained by electron-induced dissociation of H 2 O ad , described in more detail elsewhere. 23,24 A cold trap held at liquid nitrogen temperature was used for the hydrogen gas line to eliminate water. For the NAP-XPS experiments at HIPPIE a Pall GLPSIPVMM4 filter was used in addition to the cold trap.…”

Section: ■ Experimental Methodsmentioning

confidence: 99%

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Water Formation Kinetics on Co(0001) at Low and Near-Ambient Hydrogen Pressures in the Context of Fischer–Tropsch Synthesis

et al. 2023

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Understanding the kinetics of oxygen removal from catalytically active metal surfaces by hydrogen is important for several catalytic reactions such as Fischer–Tropsch synthesis, methanation of CO or CO2, and the reverse-water–gas-shift reaction. Motivated by FTS, a Co(0001) single crystal model catalyst was used to study the kinetics of oxygen removal through reaction with hydrogen. Kinetic studies in the 10–7–10–4 mbar H2 pressure regime show that water formation is first order in the surface hydrogen concentration while the order in oxygen concentration changes from one at low oxygen coverage to zero at high oxygen coverage. In situ XPS shows that the hydrogen surface concentration saturates around 10–1 mbar and on this basis the typical temperature of 450 K needed for water formation in this pressure regime can be considered as typical for high pressures as well. The absence of OH buildup during the reaction points to O + H as the rate-limiting step, with a barrier of ∼120 kJ mol–1. Such a high barrier shows that slow removal of adsorbed oxygen from the surface of reactive metal catalysts such as cobalt may be rate-limiting for the overall reaction.

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Section: ■ Experimental Methodsmentioning

confidence: 99%

“…Binding energies are reported relative to the Fermi edge. The reference spectrum for a mixed CO ad –O ad layer was obtained by dosing CO at 300 K onto the O-covered sample, while the reference spectrum for OH ad was obtained by electron-induced dissociation of H 2 O ad , described in more detail elsewhere. , …”

Section: Experimental Methodsmentioning

confidence: 99%

Water Formation Kinetics on Co(0001) at Low and Near-Ambient Hydrogen Pressures in the Context of Fischer–Tropsch Synthesis

et al. 2023

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“…Platinum is an effective redox catalyst for the formation of water in electrochemical fuel cells, stimulating considerable interest in how it interacts with water, OH, and other intermediate species. , As a result, a number of studies have investigated how water binds on the close-packed Pt surface, revealing details of how the film nucleates, , the complex mix of pentamer, hexamer, and heptamer rings that stabilizes the first layer of water, − and how the structure of this layer influences the growth and crystallization of multilayer films. − The importance of surface steps as nucleation sites was identified in the earliest STM studies, with water forming narrow “quasi-one-dimensional chains” less than 10 Å wide on the top edge of Pt steps, with more extended 2D islands nucleating on the lower terrace . Steps were also found to stabilize water on other metal surfaces, − and this, along with the importance of low coordinate sites for practical catalysts, − has spurred experiments to examine how step sites influence water adsorption on Pt. − The general conclusion is that low coordinate metal steps enhance the binding energy of water and stabilize adsorption, but there is less clarity about the precise structures formed on different surfaces or indeed the amount of water present.…”

Section: Introductionmentioning

confidence: 99%

Wetting of a Stepped Platinum (211) Surface

2023

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Steps stabilize water adsorption on metal surfaces, providing favorable binding sites for water during wetting or ice nucleation, but there is limited understanding of the local water arrangements formed on such surfaces. Here we describe the structural evolution of water on the stepped Pt(211) surface using thermal desorption, low-energy electron diffraction, and scanning tunneling microscopy to probe the water structure. At low coverage water forms linear structures comprising zigzag chains along the steps that are decorated by H-bonded rings every one or two units along the terrace. Simple 2-coordinate H-bonded chains are not observed, indicating the Pt step binds too weakly to compensate entirely for a low water H-bond coordination number. As the coverage increases, water chains assemble into a disordered (2 × 1) structure, likely made up of the same narrow water chains along the steps with little or no H-bonding between adjacent structures. The chain structure disappears as water adsorption saturates the surface to form an incommensurate, disordered network of water rings of different size. Although the steps on Pt(211) clearly stabilize water adsorption and direct growth, the surface does not support the simple 1D chains previously proposed or an ordered 2D network such as seen on other surfaces. We discuss reasons for this and the factors that determine the behavior of the first water layer on stepped metal surfaces.

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