High coverage adsorption and co-adsorption of CO and H<sub>2</sub> on Ru(0001) from DFT and thermodynamics

Zhao, Peng; He, Yurong; Cao, Dong-Bo; Wen, Xiaodong; Xiang, Huimin; Li, Yongwang; Wang, Jianguo; Jiao, Haijun

doi:10.1039/c5cp02486b

Cited by 55 publications

(39 citation statements)

References 66 publications

(137 reference statements)

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“…The contribution of vibrations to the solid surface is negligible and can be substituted by the results from DFT. 52 The gas phase term can be calculated by the equation (2):…”

Section: Thermodynamicsmentioning

confidence: 99%

Coverage and Stability of NHx Terminated Cobalt and Ruthenium Surfaces: a First Principles Investigation

Liu¹,

Nolan²

2019

Preprint

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<div>In the atomic layer deposition (ALD) of Cobalt (Co) and Ruthenium (Ru) metal using nitrogen plasma, the structure and composition of the post N-plasma NHx terminated (x = 1 or 2) metal surfaces are not well known but are important in the subsequent metal containing pulse. In this paper, we use the low-index (001) and (100) surfaces of Co and Ru as models of the metal polycrystalline thin films. The (001) surface with a hexagonal surface structure is the most stable surface and the (100) surface with a zigzag structure is the least stable surface but has high reactivity. We investigate the stability of NH and NH2 terminations on these surfaces to determine the saturation coverage of NHx on Co and Ru. NH is most stable in the hollow hcp site on (001) surface and the bridge site on the (100) surface, while NH2 prefers the bridge site on both (001) and (100) surfaces. The differential energy is calculated to find the saturation coverage of NH and NH2. We also present results on mixed NH/NH2-terminations. The results are analyzed by thermodynamics using Gibbs free energies (ΔG) to reveal temperature effects on the stability of NH and NH2 terminations. Ultra-high vacuum (UHV) and standard ALD</div><div>operating conditions are considered. Under typical ALD operating conditions we find that the most stable NHx terminated metal surfaces are 1 ML NH on Ru (001) surface (350K-550K), 5/9 ML NH on Co (001) surface (400K-650K) and a mixture of NH and NH2 on both Ru (100) and Co (100) surfaces.</div>

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“…The contribution of vibrations to the solid surface is negligible and can be substituted by the results from DFT. 52 The gas phase term can be calculated by the equation (2):…”

Section: Thermodynamicsmentioning

confidence: 99%

Coverage and Stability of NHx Terminated Cobalt and Ruthenium Surfaces: a First Principles Investigation

Liu¹,

Nolan²

2019

Preprint

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“…[19][20][21][22][23] For example, the ordered structures of CO on Co (0001), Ru(0001) and Pt (111) surfaces can be tuned by lateral interactions under different coverages. [24][25][26] In addition, the NO adsorption has been studied with both experiment and theoretical techniques on the TiO 2 (110) surface, the results found that N 2 O molecules as reduction product desorbed at 250 K. [27] The formation of N 2 O was observed to increase with NO coverage at 110 K, indicating that coverage effects play a role. [28] Theoretical calculations also demonstrated that the halfmonolayer coverage of NO on the TiO 2 (110) is in agreement with the experimental results.…”

Section: Introductionmentioning

confidence: 99%

“…Surface phase diagrams are widely used to study the most stable surface composition as a function of reaction conditions. [25,26,31] For the low-coverage surface configurations of metals, full DFT calculations are relatively computationally inexpensive and are commonly used to identify the stability of a species on the surface. In addition, linear scaling relations driven by the d-band model have been established for adsorbates at low-coverage on metal surfaces, where the slope of the scaling relations follows simple bond counting principles.…”

Section: Introductionmentioning

confidence: 99%

Scalable approach to high coverages on oxides via iterative training of a machine‐learning algorithm

2020

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Understanding the interaction of multiple types of adsorbate molecules on solid surfaces is crucial to establishing the stability of catalysts under various chemical environments. Computational studies on the high coverage and mixed coverages of reaction intermediates are still challenging, especially for transition‐metal compounds. In this work, we present a framework to predict differential adsorption energies and identify low‐energy structures under high‐ and mixed‐adsorbate coverages on oxide materials. The approach uses Gaussian process machine‐learning models with quantified uncertainty in conjunction with an iterative training algorithm to actively identify the training set. The framework is demonstrated for the mixed adsorption of CHx, NHx and OHx species on the oxygen vacancy and pristine rutile TiO2(110) surface sites. The results indicate that the proposed algorithm is highly efficient at identifying the most valuable training data, and is able to predict differential adsorption energies with a mean absolute error of ∼0.3 eV based on <25 % of the total DFT data. The algorithm is also used to identify 76 % of the low‐energy structures based on <30 % of the total DFT data, enabling construction of surface phase diagrams that account for high and mixed coverage as a function of the chemical potential of C, H, O, and N. Furthermore, the computational scaling indicates the algorithm scales nearly linearly (N1.12) as the number of adsorbates increases. This framework can be directly extended to metals, metal oxides, and other materials, providing a practical route toward the investigation of the behavior of catalysts under high‐coverage conditions.

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“…While metallic ruthenium is known to catalyze the reverse water gas shift reaction, its interaction with CO 2 has not, to our knowledge, been the subject of investigation. 5−8 The chemisorption and reaction of CO 2 on metal oxides, including RuO 2 , and metallic alloys, including Ru, are well-studied processes. 1,3 Moreover, the adsorption of CO 2 on other single-crystal metal surfaces has been extensively studied.…”

Section: Introductionmentioning

confidence: 99%

Adsorption and Dissociation of CO₂ on Ru(0001)

et al. 2017

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The adsorption and dissociation of carbon dioxide on a Ru(0001) single crystal surface was investigated by reflection–absorption infrared spectroscopy (RAIRS) and temperature-programmed desorption (TPD) spectroscopy for CO2 adsorbed at 85 K. RAIRS spectroscopy shows that the adsorption of CO2 on a Ru(0001) single crystal is partially dissociative, resulting in CO2 and CO. The CO vibrational mode was also observed to split into two distinct modes, indicating two general populations of CO present at the surface. Furthermore, a time-dependent blue-shift is observed, which is characteristic of increasing CO surface coverage. TPD showed that coverages of up to 0.3 ML were obtained, and no evidence for chemisorption of oxygen on ruthenium was found.

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High coverage adsorption and co-adsorption of CO and H₂ on Ru(0001) from DFT and thermodynamics

Cited by 55 publications

References 66 publications

Coverage and Stability of NHx Terminated Cobalt and Ruthenium Surfaces: a First Principles Investigation

Coverage and Stability of NHx Terminated Cobalt and Ruthenium Surfaces: a First Principles Investigation

Scalable approach to high coverages on oxides via iterative training of a machine‐learning algorithm

Adsorption and Dissociation of CO₂ on Ru(0001)

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High coverage adsorption and co-adsorption of CO and H2 on Ru(0001) from DFT and thermodynamics

Cited by 55 publications

References 66 publications

Coverage and Stability of NHx Terminated Cobalt and Ruthenium Surfaces: a First Principles Investigation

Coverage and Stability of NHx Terminated Cobalt and Ruthenium Surfaces: a First Principles Investigation

Scalable approach to high coverages on oxides via iterative training of a machine‐learning algorithm

Adsorption and Dissociation of CO2 on Ru(0001)

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High coverage adsorption and co-adsorption of CO and H₂ on Ru(0001) from DFT and thermodynamics

Adsorption and Dissociation of CO₂ on Ru(0001)