Mechanistic investigation on ethanol‐to‐butadiene conversion reaction over metal oxide clusters

Butera, Valeria; Tanabe, Yusuke; Shinke, Yu; Miyazawa, Tomohisa; Fujitani, Tadahiro; Kayanuma, Megumi; Choe, Yoong‐Kee

doi:10.1002/qua.26494

Cited by 14 publications

(15 citation statements)

References 42 publications

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“…Investigations based on a cluster model approach can be advantageous over periodic boundary condition (PBC) methods because they enable the use of hybrid functionals at a lower computational cost, and, therefore, a highly accurate description of electronic properties. Moreover, cluster approaches are more appropriate for studying charged systems, thanks to the ability to add/subtract a charge carrier without suffering from interactions with similar charge carriers due to periodic boundary conditions. , Due to their reduced size, cluster approaches can be used to investigate complex reaction mechanisms, allowing for the interception of all the involved stationary points, including the more complex transition states. − However, PBC calculations allow for modeling more extended surfaces and provide an accurate description of the structural properties of the surface and molecular adsorbates. The complementarity of the two computational methods can therefore lead to an in-depth understanding of the structure–property relationship …”

Section: Introductionmentioning

confidence: 99%

DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO₂

Butera

Detz

2022

ACS Appl. Energy Mater.

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Obtaining chemicals and fuels from the reduction of carbon dioxide (CO2) represents a promising strategy to mitigate the growing greenhouse gas emissions. Because of the high thermodynamic stability of CO2, the real challenge is the development of efficient and selective catalysts. In this regard, photocatalysis is receiving much attention because it exclusively relies on energy input from sunlight. Gallium nitride (GaN) semiconductors can effectively promote the CO2 reduction. Moreover, the addition on the semiconductor surfaces of transition metal nanoparticles, such as Rh and Pt, can further improve the efficiency and selectivity toward CH4 rather than CO, along with improving the optical absorptions in the visible spectral region by decreasing the wide band gap of the pristine GaN. Water is commonly used as an atomic hydrogen donor for CO2 reduction. In this regard, GaN was previously reported as an excellent photocatalyst for water oxidation. Here, we present a density functional theory investigation based on a cluster model approach to shed light on the effective role of the metal nanoparticles on the CO2 reduction in the presence of water. Our calculations have underlined a more favored dissociative adsorption of H2O with respect to CO2. Moreover, while the dissociative H2O adsorption on the GaN surface occurs without the involvement of the Rh metal, the role of the metal center in activating the CO2 molecule is found to be crucial. Highest occupied molecular orbital–lowest unoccupied molecular orbital gaps and calculated absorption spectra have shown that the presence of the adsorbed nanoparticles not only intensifies the absorption next to the UV region but also extends it to all visible regions. Particularly, while the presence of Rh exhibits a stronger light absorption property in the visible region, enhanced in the blue-green region, Pt nanoparticles have a clear red-shift effect.

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Section: Introductionmentioning

confidence: 99%

DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO₂

Butera

Detz

2022

ACS Appl. Energy Mater.

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“…[34][35][36][37][38][39][40][41][42] Motivated by these promising results, in a preliminary work, [24] we have investigated the photocatalytic activity of the undoped GaN and GaN doped with one single Mg atom, along with the CO 2 reduction to methanol. The DFT investigation was carried out using a cluster model approach, that has some advantages over periodic boundary condition (PBC) calculations such us the utilization of hybrid functionals, [43][44][45] and the investigation of complex reaction mechanism, [46,47] at lower computational cost than periodic boundary condition (PBC) calculations. However, cluster model approaches do not allow for the investigation of extended surfaces and heterojunctions, which can be more conveniently performed by means of PBC calculations.…”

Section: Introductionmentioning

confidence: 99%

Gallium Nitride‐based Materials as Promising Catalysts for CO₂ Reduction: A DFT Study on the Effect of CO₂ Coverage and the Incorporation of Mg Doping or Substitutional In

et al. 2022

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Catalytic CO 2 conversion to fuels and chemicals is important for mitigating the climate change and reducing the dependence on fossil resources. In order to achieve this goal on a large industrial level, effective catalysts need to be developed. Among them, gallium nitride (GaN) and related Mg-doped and In-alloyed systems have been proven as efficient materials for the reduction of highly stable CO 2 molecules. This work presents a density functional theory (DFT) investigation, performing periodic boundary condition (PBC) calculations which allow to employ a more extended surface for a detailed analysis of the CO 2 coverage, and the effect of Mg doping and In alloying on the CO 2 adsorption and its conversion to CO. The results show the great potential of GaN(100) surfaces to simultaneously bind and strongly activate multiple CO 2 molecules, which is a crucial aspect for an efficient CO 2 conversion process. Moreover, the presence of Mg-dopant on the top layer is found to be more beneficial for the CO 2 adsorption and activation with respect to both the pristine and In-alloyed system, and this effect is further improved by the inclusion of a second impurity on the top layer. In line with the previous experimental findings, these calculations support the potential of pristine GaN(100) to catalyze the CO 2 -to-CO reduction. The results presented here offer crucial information for the development of more efficient and selective catalysts for the CO 2 reduction.

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“…The ability to add/subtract a charge carrier without suffering from interactions with similar charge carriers due to PBC ( Butera and Caspary Toroker, 2016 ) makes CAs suitable for the study of charged systems. Thanks to the reduced size, the CA can be used to intercept all the stationary points, including the more complex transition states, involved in the catalytic cycle, and to determine the rate-determining states ( D’Arienzo et al, 2017 ; Butera et al, 2018 ; Butera et al, 2021 ). However, the selection of the cluster models is not trivial.…”

Section: Introductionmentioning

confidence: 99%

d-Glucose Adsorption on the TiO2 Anatase (100) Surface: A Direct Comparison Between Cluster-Based and Periodic Approaches

et al. 2021

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Titanium dioxide (TiO2) has been extensively studied as a suitable material for a wide range of fields including catalysis and sensing. For example, TiO2-based nanoparticles are active in the catalytic conversion of glucose into value-added chemicals, while the good biocompatibility of titania allows for its application in innovative biosensing devices for glucose detection. A key process for efficient and selective biosensors and catalysts is the interaction and binding mode between the analyte and the sensor/catalyst surface. The relevant features regard both the molecular recognition event and its effects on the nanoparticle electronic structure. In this work, we address both these features by combining two first-principles methods based on periodic boundary conditions and cluster approaches (CAs). While the former allows for the investigation of extended materials and surfaces, CAs focus only on a local region of the surface but allow for using hybrid functionals with low computational cost, leading to a highly accurate description of electronic properties. Moreover, the CA is suitable for the study of reaction mechanisms and charged systems, which can be cumbersome with PBC. Here, a direct and detailed comparison of the two computational methodologies is applied for the investigation of d-glucose on the TiO2 (100) anatase surface. As an alternative to the commonly used PBC calculations, the CA is successfully exploited to characterize the formation of surface and subsurface oxygen vacancies and to determine their decisive role in d-glucose adsorption. The results of such direct comparison allow for the selection of an efficient, finite-size structural model that is suitable for future investigations of biosensor electrocatalytic processes and biomass conversion catalysis.

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Mechanistic investigation on ethanol‐to‐butadiene conversion reaction over metal oxide clusters

Cited by 14 publications

References 42 publications

DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO₂

DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO₂

Gallium Nitride‐based Materials as Promising Catalysts for CO₂ Reduction: A DFT Study on the Effect of CO₂ Coverage and the Incorporation of Mg Doping or Substitutional In

d-Glucose Adsorption on the TiO2 Anatase (100) Surface: A Direct Comparison Between Cluster-Based and Periodic Approaches

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Mechanistic investigation on ethanol‐to‐butadiene conversion reaction over metal oxide clusters

Cited by 14 publications

References 42 publications

DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO2

DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO2

Gallium Nitride‐based Materials as Promising Catalysts for CO2 Reduction: A DFT Study on the Effect of CO2 Coverage and the Incorporation of Mg Doping or Substitutional In

d-Glucose Adsorption on the TiO2 Anatase (100) Surface: A Direct Comparison Between Cluster-Based and Periodic Approaches

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Product

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DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO₂

DFT Study of GaN Clusters Decorated with Rh and Pt Nanoparticles for the Photochemical Reduction of CO₂

Gallium Nitride‐based Materials as Promising Catalysts for CO₂ Reduction: A DFT Study on the Effect of CO₂ Coverage and the Incorporation of Mg Doping or Substitutional In