Lattice Strain and Surface Activity of Ternary Nanoalloys under the Propane Oxidation Condition

Kareem, Haval; Maswadeh, Yazan; Wu, Zhipeng; Leff, Asher C.; Cheng, Huhu; Shan, Shiyao; Wang, Shan; Robinson, Richard; Caracciolo, Dominic; Langrock, Alex; Mackie, David M.; Tran, Dat T.; Petkov, Valeri; Zhong, Chuan‐Jian

doi:10.1021/acsami.1c24007

Cited by 7 publications

(4 citation statements)

References 59 publications

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“…Moreover, one can even explore the inclusion of a third species in the alloy, aiming to enhance the activity of the active metal even further. Several examples from the literature showcase the intriguing synergy exhibited by such ternary alloys. − For instance, Maluf and Assaf used a Mo promoter in a solid-phase Ni catalyst to improve its activity for methane steam reforming . These alloys have been previously investigated in such diverse areas as hydrocarbon conversion, dry reforming of methane, , and thermocatalytic decomposition of methane , which are similar to the reaction under consideration.…”

Section: Introductionmentioning

confidence: 99%

“…Several examples from the literature showcase the intriguing synergy exhibited by such ternary alloys. − For instance, Maluf and Assaf used a Mo promoter in a solid-phase Ni catalyst to improve its activity for methane steam reforming . These alloys have been previously investigated in such diverse areas as hydrocarbon conversion, dry reforming of methane, , and thermocatalytic decomposition of methane , which are similar to the reaction under consideration. Hence, the main objective of this study is to understand the effect of such a promoter on the reactivity of a Ni-based alloy within a low-melting-point solvent metal, namely Bi.…”

Section: Introductionmentioning

confidence: 99%

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Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH₄ Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study

Erbasan,

Ustunel,

Toffoli

et al. 2024

ACS Appl. Energy Mater.

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Pyrolysis of methane using molten metal catalysts in bubble column reactors presents a cleaner and coking-free alternative for hydrogen production from natural gas due to its lack of direct CO 2 emissions. Bubble column reactors overcome coking as the byproduct carbon material floats to the top due to its lower density with respect to the molten metal and can be collected by physical means. Typically, the catalysts used in these systems consist of a low-melting-point solvent metal such as Sn or Bi, along with a higher melting point active component such as Ni. In this study, we present a first-principles investigation that explores the impact of a third component, a promoter, on the reactivity of a Bi−Ni molten alloy. Specifically, we examine Al and Cu as promoters and compare their effects. Unlike previous literature that mostly relies on static nudged elastic bands and free-energy-based calculations, we develop a comprehensive ab initio molecular dynamics-based protocol to provide a detailed account of the reaction mechanism. Our direct rate calculations reveal that, overall, including either promoter at 10 or 20% leads to a better performance than using an unpromoted Ni−Bi binary alloy. To overcome the intrinsic difficulties associated with rate calculations, we have performed a large number of ab initio molecular dynamics calculations and have analyzed the H dissociation times for each reaction step involved in the reaction mechanisms. Our findings reveal that overall Cu outperforms Al as a promoter under the simulation conditions employed. To better understand this outcome, we carefully examined each dissociation event and identified several intriguing trends, including the contrasting contributions of Al and Cu to reactivity. We have further rationalized our results with the help of simple descriptors such as binding energy and partial Bader charges in binary metal clusters and have found that the strength of the interaction of different metal species in the alloy with one another and the product fragments in the immediate neighborhood of the reaction as well as relative partial charges correlate very well with dissociation time data. The analysis methods developed in this study will be used in future research, enabling the screening of a broader range of promoters and facilitating the design of these promising energy production systems.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH₄ Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study

Erbasan,

Ustunel,

Toffoli

et al. 2024

ACS Appl. Energy Mater.

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“…[ 6 ] However, the complicated evolution information of surface reconstruction makes it challenging to identify the structural model of actual active sites and, in turn, to conduct the substantial and reliable mechanism analysis. [ 7 ] To eliminate the impact of reconstructing, an effective strategy involves constructing the steady configuration during catalysis to directly trigger the catalytic cycle without structural transformation. For example, Sun et al reported the atomically dispersed Ru on Ni–V layered double hydroxide scaffold with the bifunctional reactive sites, which can preserve the surface configuration and suppress the occurrence of surface restructuring through a strongly atomic metal–support interaction.…”

Section: Introductionmentioning

confidence: 99%

Stable Strain State of Single‐Twinned AgPdF Nanoalloys under Formate Oxidation Reaction

et al. 2023

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Surface reconstruction as common phenomenon during catalysis complicates the prediction and modeling on catalytic activity of the nanoalloy, hence developing a stable structure to be resistant to surface restructuring would provide an ideal prototype for substantial and reliable mechanism analysis. Herein, the single‐twinned structure in inverse AgPdF catalyst is constructed to enhance the catalytic activity and stability for the formate oxidation reaction (FOR). The single‐twinned AgPdF nanoalloy (t‐AgPdF) catalyst exhibits an enhanced peak current density of 4.6 A mgPd−1, a reduced onset potential of 0.44 V, a higher activity retention of 55.7% after 600 cycles, and a longer activity retention time of 55.9 h. Additionally, the t‐AgPdF catalyst presents a higher hydrogen generation rate of 1.11 mL mgPd−1 than that of single‐crystalline AgPd nanoalloy (AgPd) catalyst, and density functional theory calculations reveal that t‐AgPdF(111) surface exhibits a reduced activation energy of 0.59 eV for formate decomposition reaction. Impressively, the t‐AgPdF maintains compressive and tensile strain state along the Σ3 twin boundaries before and after the FOR, in contrast to AgPd. This is the first time to reveal that the nanotwinned structures contribute inverse t‐AgPdF catalysts the catalytic active sites with stable strain state since starting reaction for the FOR.

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“…Many in situ/operando FTIR (Fourier transform infrared spectroscopy), Raman, XAS (X‐ray absorption spectroscopy), XPS (X‐ray photoelectron spectroscopy), XRD (X‐ray diffraction), etc., have been used for catalyst characterizations which largely capture the average molecular or atomic information under reaction conditions. [ 22–47 ] In comparison, in situ/operando TEM is relatively new, which enables the ability to capture individual atom or molecule information under the reaction conditions. In other words, it provides information with atomic, molecular and sometimes nanoscale/microscale resolutions depending on the complexity of the sample system and the instrumental measurement configuration.…”

Section: Introductionmentioning

confidence: 99%

Insights into Heterogeneous Catalysts under Reaction Conditions by In Situ/Operando Electron Microscopy

Cheng

Wang

Chen

et al. 2022

Advanced Energy Materials

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The advancement of clean energy and environment depends strongly on the development of efficient catalysts in a wide range of heterogeneous catalytic reactions, which has benefited from transmission electron microscopic techniques in determining the atomic‐scale morphologies and structures. However, it is the morphology and structure under the catalytic reaction conditions that determine the performance of the catalyst, which has captured a surge of interest in developing and applying in situ/operando transmission electron microscopic techniques in heterogeneous catalysis. The major theme of this review is to highlight some of the most recent insights into heterogeneous catalysts under the relevant reaction conditions using in situ/operando transmission electron microscopic techniques. Rather than a comprehensive overview of the basic principles of in situ/operando techniques, this review focuses on the insights into the atomic‐scale/nanoscale details of various catalysts ranging from single‐component to multicomponent catalysts under heterogeneous catalytic, electrocatalytic, and photocatalytic reaction conditions involving both gas–solid and liquid–solid interfaces. This focus is coupled with discussions of the correlation of the atomic, molecular, and nanoscale morphology, composition, and structure with the catalytic properties under the reaction conditions, shining light on the challenges and opportunities in design of nanostructured catalysts for clean and sustainable energy applications.

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Lattice Strain and Surface Activity of Ternary Nanoalloys under the Propane Oxidation Condition

Cited by 7 publications

References 59 publications

Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH₄ Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study

Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH₄ Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study

Stable Strain State of Single‐Twinned AgPdF Nanoalloys under Formate Oxidation Reaction

Insights into Heterogeneous Catalysts under Reaction Conditions by In Situ/Operando Electron Microscopy

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Lattice Strain and Surface Activity of Ternary Nanoalloys under the Propane Oxidation Condition

Cited by 7 publications

References 59 publications

Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH4 Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study

Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH4 Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study

Stable Strain State of Single‐Twinned AgPdF Nanoalloys under Formate Oxidation Reaction

Insights into Heterogeneous Catalysts under Reaction Conditions by In Situ/Operando Electron Microscopy

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Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH₄ Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study

Insights into Reaction Mechanisms in Liquid Metals from Density Functional Theory: CH₄ Pyrolysis in BiNiX (X = Cu, Al) Molten Metals as a Case Study