Molecule Saturation Boosts Acetylene Semihydrogenation Activity and Selectivity on a Core‐Shell Ruthenium@Palladium Catalyst

Zhu, Chengshen; Xu, Wenlong; Liu, Fang; Luo, Jie; Lu, Junling; Li, Wei‐Xue

doi:10.1002/anie.202300110

Cited by 5 publications

(6 citation statements)

References 81 publications

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“…5 This could be realized commercially over supported Pd-based catalysts, but they suffer from poor selectivity. 6,7 Gold as a latent green catalyst has been found to be selective for the hydrogenation of some unsaturated groups, such as C�O and C�C, owing to its unique nature to desorb olefins at lower temperatures than alkynes. 8,9 In the past few decades, much effort has been devoted to the development of novel Au catalysts, including the modification of Au particle size, the introduction of second metals, or the selection of the suitable supports.…”

Section: Introductionmentioning

confidence: 99%

“…About 75% of ethylene is obtained by naphtha cracking along with the generation of acetylene impurities that would irreversibly poison polymerization catalysts. , Consequently, the modern polyolefin industry demands the acetylene concentration in the ethylene feed to be less than 1 ppm. , Considering the atomic economy, selective acetylene hydrogenation to ethylene is regarded as the most state-of-the-art route for ethylene purification . This could be realized commercially over supported Pd-based catalysts, but they suffer from poor selectivity. , …”

Section: Introductionmentioning

confidence: 99%

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Construction of Enriched Metal Vacancies to Enhance Catalytic Behavior for Selective Hydrogenation Over Au–Cu Nanoalloys

Zheng,

Zhu,

et al. 2024

Ind. Eng. Chem. Res.

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Hydrogenation of unsaturated C�C groups is a promising way to realize ethylene purification in petrochemical processes and produce value-added products. Gold catalysts are known to exhibit satisfactory selectivity toward olefins. However, it still remains a grand challenge to improve the activity and inhibit the heavy coke effect while balancing the selectivity. This article describes the construction of Cu vacancies at an abrupt surface over a Au−Cu alloy catalyst to effectively promote the activation and dissociation of hydrogen, thereby reducing the activation energy barrier. More importantly, the generation of abundant Cu vacancies contributes to the electronic interaction with the adjacent second metal to generate coordination unsaturated and electron-deficient Au species, which facilitates the desorption of product intermediates. Consequently, the activity and selectivity of the acid-etched Au 3 Cu 1 /TiO 2 are much higher than those of the untreated Au−Cu and monometallic Au catalysts. This report opens up promising possibilities for engineering highly efficient heterogeneous gold catalysts.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Construction of Enriched Metal Vacancies to Enhance Catalytic Behavior for Selective Hydrogenation Over Au–Cu Nanoalloys

Zheng,

Zhu,

et al. 2024

Ind. Eng. Chem. Res.

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“…Catalysis plays a pivotal role in a wide range of chemical processes, enabling the synthesis of vital materials and the conversion of raw resources into value-added products. , In the quest for sustainable and environmentally friendly chemical transformations, the development of efficient catalysts that selectively activate target molecules is of utmost importance. − Supported transition metals (TMs) are widely used to improve the catalytic activity and selectivity for their great tunability of geometry structure, − composition, , size, − and strong metal–support interaction − among others. Talyor proposed nearly one century ago that unsaturated active sites control the reactivity, and Boudart classified the catalytic reactions as either structure sensitive or insensitive .…”

Section: Introductionmentioning

confidence: 99%

Structure Sensitivity of Metal Catalysts Revealed by Interpretable Machine Learning and First-Principles Calculations

Shu,

Li,

Liu

et al. 2024

J. Am. Chem. Soc.

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The nature of the active sites and their structure sensitivity are the keys to rational design of efficient catalysts but have been debated for almost one century in heterogeneous catalysis. Though the Brønsted−Evans−Polanyi (BEP) relationship along with linear scaling relation has long been used to study the reactivity, explicit geometry, and composition properties are absent in this relationship, a fact that prevents its exploration in structure sensitivity of supported catalysts. In this work, based on interpretable multitask symbolic regression and a comprehensive first-principles data set, we discovered a structure descriptor, the topological under-coordinated number mediated by number of valence electrons and the lattice constant, to successfully address the structure sensitivity of metal catalysts. The database used for training, testing, and transferability investigation includes bond-breaking barriers of 20 distinct chemical bonds over 10 transition metals, two metal crystallographic phases, and 17 different facets. The resulting 2D descriptor composing the structure term and the reaction energy term shows great accuracy to predict the reaction barriers and generalizability over the data set with diverse chemical bonds in symmetry, bond order, and steric hindrance. The theory is physical and concise, providing a constructive strategy not only to understand the structure sensitivity but also to decipher the entangled geometric and electronic effects of metal catalysts. The insights revealed are valuable for the rational design of the sitespecific metal catalysts.

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“…Selective catalytic hydrogenation of acetylene impurities in an ethylene-rich stream is an important industrial process in the production of polyethylene feedstock. , With the increasingly urgent societal requirement for green chemical processes, more stringent requirements have been put forward for producing polymer-grade ethylene in which the acetylene content must be reduced to <1 ppm. , Consequently, the efficient hydrogenation of acetylene to ethylene has become a key challenge in catalysis. Pd-based catalysts are considered the most active materials at present and are thus widely used for this reaction industrially under mild reaction conditions .…”

Section: Introductionmentioning

confidence: 99%

Metal–Organic Framework-Derived Ni–S/C Catalysts for Selective Alkyne Hydrogenation

Li,

Weng,

McCue

et al. 2023

ACS Appl. Mater. Interfaces

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A carbon matrix-supported Ni catalyst with surface/ subsurface S species is prepared using a sacrificial metal−organic framework synthesis strategy. The resulting highly dispersed Ni− S/C catalyst contains surface discontinuous and electron-deficient Ni δ+ sites modified by p-block S elements. This catalyst proved to be extremely active and selective for alkyne hydrogenation. Specifically, high intrinsic activity (TOF = 0.0351 s −1 ) and superior selectivity (>90%) at complete conversion were achieved, whereas an analogous S-free sample prepared by the same synthetic route performed poorly. That is, the incorporation of S in Ni particles and the carbon matrix exerts a remarkable positive effect on catalytic behavior for alkyne hydrogenation, breaking the activity−selectivity trade-off. Through comprehensive experimental studies, enhanced performance of Ni−S/C was ascribed to the presence of discontinuous Ni ensembles, which promote desorption of weakly π-bonded ethylene and an optimized electronic structure modified via obvious p−d orbital hybridization.

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Molecule Saturation Boosts Acetylene Semihydrogenation Activity and Selectivity on a Core‐Shell Ruthenium@Palladium Catalyst

Cited by 5 publications

References 81 publications

Construction of Enriched Metal Vacancies to Enhance Catalytic Behavior for Selective Hydrogenation Over Au–Cu Nanoalloys

Construction of Enriched Metal Vacancies to Enhance Catalytic Behavior for Selective Hydrogenation Over Au–Cu Nanoalloys

Structure Sensitivity of Metal Catalysts Revealed by Interpretable Machine Learning and First-Principles Calculations

Metal–Organic Framework-Derived Ni–S/C Catalysts for Selective Alkyne Hydrogenation

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