Impurity Control in Catalyst Design: The Role of Sodium in Promoting and Stabilizing Co and Co<sub>2</sub>C for Syngas Conversion

Asundi, Arun S.; Hoffman, Adam S.; Nathan, S.; Boubnov, Alexey; Bare, Simon R.; Bent, Stacey F.

doi:10.1002/cctc.202001703

Cited by 8 publications

(3 citation statements)

References 44 publications

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“…Doping can be exploited to tailor the kinetics, selectivity, and stability of catalyst toward specific reactions. [39,40] As a platinum-group metal, Pd has similar electronic properties to Pt, but its stronger H absorption and adsorption behavior result in slow reaction rates in acidic-HOR. [10] Lattice distortions from the presence of B in bulk Pd [41] change its physical properties and B-doping modifies its catalytic activity.…”

Section: Resultsmentioning

confidence: 99%

Controlled Doping of Electrocatalysts through Engineering Impurities

et al. 2022

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Fuel cells recombine water from H2 and O2 thereby can power, for example, cars or houses with no direct carbon emission. In anion‐exchange membrane fuel cells (AEMFCs), to reach high power densities, operating at high pH is an alternative to using large volumes of noble metals catalysts at the cathode, where the oxygen‐reduction reaction occurs. However, the sluggish kinetics of the hydrogen‐oxidation reaction (HOR) hinders upscaling despite promising catalysts. Here, the authors observe an unexpected ingress of B into Pd nanocatalysts synthesized by wet‐chemistry, gaining control over this B‐doping, and report on its influence on the HOR activity in alkaline conditions. They rationalize their findings using ab initio calculations of both H‐ and OH‐adsorption on B‐doped Pd. Using this “impurity engineering” approach, they thus design Pt‐free catalysts as required in electrochemical energy conversion devices, for example, next generations of AEMFCs, that satisfy the economic and environmental constraints, that is, reasonable operating costs and long‐term stability, to enable the “hydrogen economy.”

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Section: Resultsmentioning

confidence: 99%

Controlled Doping of Electrocatalysts through Engineering Impurities

et al. 2022

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“…Previous studies suggested that the added alkali metals may act as electron donors to cobalt, leading to stronger adsorption and enhanced dissociation of CO, which also benefits the formation of the Co 2 C phase. 47,50 The olefin/paraffin (O/P) ratio and the CO 2 selectivity also increased upon alkali addition. 6 Furthermore, the FTS reaction has been shown to be a structure-sensitive reaction, as different facets of Co 2 C were found to exhibit distinct catalytic activities toward CO dissociation, hydrogenation, and chain growth.…”

Section: ■ Discussionmentioning

confidence: 99%

Theoretical Insights into Morphologies of Alkali-Promoted Cobalt Carbide Catalysts for Fischer–Tropsch Synthesis

Zhang

Zhong

et al. 2021

J. Phys. Chem. C

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Co2C catalysts were found to be structure-sensitive during Fischer–Tropsch synthesis (FTS), and reaction-induced Co2C nanoprisms exposing the (101) and (020) facets exhibited superior olefin selectivity, low methane selectivity, and high activity under mild conditions. Alkali metal promoters benefit the formation and stabilization of Co2C nanoprisms, although mechanistic understanding and theoretical support are lacking due to the great complexity of this catalytic reaction and the difficulty in characterizing the detailed structural changes. Here, density functional theory (DFT) calculations and ab initio atomistic thermodynamics simulations are combined to elucidate the “promoter–structure” relationship of Co2C catalysts decorated with different alkali metal promoters. Co- and C-terminated and stoichiometric low-index surfaces including (020), (101), (111), (011), and (110) are considered. Evolution of the equilibrium morphology versus K2O coverage (θK2O) and carbon chemical potential (μC) as determined by the temperature, pressure, and the H2/CO ratio are predicted. We find that increasing θK2O facilitates the preferential exposure of the (020) and (101) facets with different terminations at diverse μC, which are the active surfaces for Fischer–Tropsch to olefins (FTO). For θK2O = 1/6 ML, these two surfaces are predicted to cover 100, 53.4, and 48.4% of the exposed surface area at μC of −7.5, −8.5, and −9.5 eV, respectively, compared with 8.6, 18.3, 26.2% without this promoter. The dominant exposure of these two facets explains the experimentally observed structure of Co2C nanoprisms with a parallelepiped shape. Additionally, the promotional effect extends the preference of most Co- and C-terminated facets over stoichiometric facets to a larger range of μC. Furthermore, Na, K, and Rb promoters are predicted to have stronger effects than Li in stabilizing these two facets, which is also consistent with available experimental observations. Insights from this theoretical work provide a rational understanding of the promotional effect of alkali metals on the morphology of the Co2C catalyst, which may facilitate the design of more efficient FTO catalysts with controlled surface structures.

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“…Atomic layer deposition (ALD) is an advanced thin film deposition technique that has gained wide interest for various technological applications in microelectronics, , catalysis, − and renewable energy. − ALD can be used to deposit a broad range of thin-film materials, including oxides, sulfides, and nitrides, as well as metals such as Ni, Cu, and noble metals. , ALD is a valuable vapor deposition technique due to its unique growth process wherein the precursors undergo alternating and self-limiting surface reactions. The layer-by-layer growth mechanism ideally leads to conformality and excellent control over the thickness.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Growth in Atomic Layer Deposition of Ruthenium Metal: The Role of Surface Diffusion and Nucleation Sites

Rothman,

Werbrouck,

Bent

2023

Chem. Mater.

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Thermal atomic layer deposition (ALD) of metals on metal oxide surfaces is challenging due to nucleation delays caused by few chemisorption sites and poor material transport at the substrate. Here, we investigate ways to enhance the nucleation and growth of ruthenium (Ru) using ALD with the Ru(Cp) 2 precursor and O 2 as a coreactant. We explore the effects of functionalizing the substrate surface with small organometallic molecules, such as trimethylaluminum and diethylzinc, on the nucleation and growth of Ru layers. Our results demonstrate an enhancement effect, which is reflected in higher nuclei density and a larger average diameter of the deposited Ru nanoparticles for the same number of cycles. We hypothesize that the increase in nucleation is attributed to the augmentation of nucleation sites, while the increase in growth can be attributed to the elevated surface diffusivity. As a result, the transport processes on the surface, such as coalescence and nanoparticle diffusion, are enhanced compared to the nonpretreated substrate. We support this conclusion by examining the morphology of the Ru layers using scanning electron microscopy, combining it with a theoretical growth model and gaining insights into the underlying mechanism of the enhancement effect. This study contributes to the understanding of ALD processes and provides insights into how small organometallic molecules can be used to modify surface diffusion, leading to the enhanced growth of thin films.

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Impurity Control in Catalyst Design: The Role of Sodium in Promoting and Stabilizing Co and Co₂C for Syngas Conversion

Cited by 8 publications

References 44 publications

Controlled Doping of Electrocatalysts through Engineering Impurities

Controlled Doping of Electrocatalysts through Engineering Impurities

Theoretical Insights into Morphologies of Alkali-Promoted Cobalt Carbide Catalysts for Fischer–Tropsch Synthesis

Enhanced Growth in Atomic Layer Deposition of Ruthenium Metal: The Role of Surface Diffusion and Nucleation Sites

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Impurity Control in Catalyst Design: The Role of Sodium in Promoting and Stabilizing Co and Co2C for Syngas Conversion

Cited by 8 publications

References 44 publications

Controlled Doping of Electrocatalysts through Engineering Impurities

Controlled Doping of Electrocatalysts through Engineering Impurities

Theoretical Insights into Morphologies of Alkali-Promoted Cobalt Carbide Catalysts for Fischer–Tropsch Synthesis

Enhanced Growth in Atomic Layer Deposition of Ruthenium Metal: The Role of Surface Diffusion and Nucleation Sites

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Impurity Control in Catalyst Design: The Role of Sodium in Promoting and Stabilizing Co and Co₂C for Syngas Conversion