Confining isolated atoms and clusters in crystalline porous materials for catalysis

Liu, Lichen; Corma, Avelino

doi:10.1038/s41578-020-00250-3

Cited by 267 publications

(195 citation statements)

References 272 publications

(269 reference statements)

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“…[7,8] Porous materials are proven superior support because its large surface area provides numerous sites for metal nanoparticle loading and reactions. [9] Further, oriented structure (Figure S1, Supporting Information). Transmission electron microscope (TEM) images confirm the high porosity, with a uniform pore size ≈10 nm (Figure 2B).…”

Section: Introductionmentioning

confidence: 99%

“…[ 7,8 ] Porous materials are proven superior support because its large surface area provides numerous sites for metal nanoparticle loading and reactions. [ 9 ] Further, oriented diffusion and accumulation of reactants in the micropores can be achieved through surface modification of porous support, thus creating “hot‐spot” for enhanced reaction kinetics. [ 10 ] Moreover, our recent study show that porous carbon support itself can act as catalyst for reactions such as peroxide‐activation.…”

Section: Introductionmentioning

confidence: 99%

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Constructing the Support as a Microreactor and Regenerator for Highly Active and In Situ Regenerative Hydrogenation Catalyst

Zhao

Liu

et al. 2021

Adv Funct Materials

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The demands for efficient and robust heterogeneous hydrogenation catalysts have triggered extensive research to optimize the structures of metal catalytic centers, but the potential of support construction for enhanced hydrogenation performance has been overlooked. This study introduces a hierarchically ordered porous poly(2,6-diaminopyridine) (PDAP) as a Pd nanoparticle support for hydrogenation removal of recalcitrant pollutants in water purification. The PDAP support acts as a sorbent and microreactor to enhance the proximity of targeted water pollutants and reactive hydrogen atom species, achieving unprecedently high water purification efficiency. The PDAP support also acts as a catalyst in mediating peroxide-activation for oxidative destruction of Pd poisons (e.g., reduced sulfur), achieving in situ regeneration of poisoned Pd catalysis centers. The high activity and in situ regenerativity achieved by rational construction of the support structure sheds light on a new approach for designing efficient and robust heterogeneous hydrogenation catalysts.

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“…[7,8] Porous materials are proven superior support because its large surface area provides numerous sites for metal nanoparticle loading and reactions. [9] Further, oriented structure (Figure S1, Supporting Information). Transmission electron microscope (TEM) images confirm the high porosity, with a uniform pore size ≈10 nm (Figure 2B).…”

Section: Introductionmentioning

confidence: 99%

“…[ 7,8 ] Porous materials are proven superior support because its large surface area provides numerous sites for metal nanoparticle loading and reactions. [ 9 ] Further, oriented diffusion and accumulation of reactants in the micropores can be achieved through surface modification of porous support, thus creating “hot‐spot” for enhanced reaction kinetics. [ 10 ] Moreover, our recent study show that porous carbon support itself can act as catalyst for reactions such as peroxide‐activation.…”

Section: Introductionmentioning

confidence: 99%

Constructing the Support as a Microreactor and Regenerator for Highly Active and In Situ Regenerative Hydrogenation Catalyst

Zhao

Liu

et al. 2021

Adv Funct Materials

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“…[12][13] A promising solution to both issues is encapsulation of the active species into inert frameworks such as zeolites or MOFs, [14][15][16][17][18][19][20][21][22] which hinder sintering by two mechanisms: physical restriction to growth by confinement in the zeolite pore, and pinning of single atoms and clusters to particular binding sites in the framework. [23][24][25] In the case of physical confinement, there are several recent synthetic methods which produce trapped particles of Pt or Pd inside zeolite pores, either by co-precipitation of precursors of both metal and zeolite, or by mechanical trapping via the 2D 3D condensation of the framework, as was recently demonstrated for MWW by Corma et al, [26][27] and IPC-2 and IPC-4 by Cejka et al [28][29] It is difficult to precisely maintain the size distribution and thermal stability of the produced clusters via chemical means. However, these methods have shown excellent promise in catalytic tests towards reactions such as nitroarene hydrogenation and dehydrogenation of propane to propylene.…”

Section: Introductionmentioning

confidence: 99%

Migration of Zeolite-Encapsulated Pt and Au Under Reducing Atmospheres

Hou¹,

Heard²

2021

Preprint

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Unbiased density functional global optimisation calculations, followed by kinetic Monte Carlo simulations are used to enumerate the potential energy surfaces for migration of noble metals Pt and Au inside the pore system of siliceous zeolite LTA. The effects of reducing adsorbates CO and H2 are determined. It is found that the two metals differ significantly in the strength and type of interaction with the framework, with strong, framework breaking interactions between Pt and and the zeolite, but only weak dispersive interactions between Au and the zeolite. Adsorbates are found to dramatically interfere with Pt-framework binding, leading to poorer atom-trapping, enhanced metal migration and faster equilibration.

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“…micropores) 15 are two widely adopted methodologies to achieve for higher stability. However, too strong MSI might over stabilize the active sites, hindering its activation to reactants/intermediates 14,16 ; con nement of the metal species in micropores might also limit mass transfers 15,17 . Consequently, a seesaw relation between stability and activity have been often observed, obscuring the tremendous efforts for optimizing the catalytic performance of SADCs [18][19][20] .…”

Section: Introductionmentioning

confidence: 99%

“…Increasing metal-support interactions (MSIs) 13,14 or con ning the active metal species in restrained spaces (eg. micropores) 15 are two widely adopted methodologies to achieve for higher stability. However, too strong MSI might over stabilize the active sites, hindering its activation to reactants/intermediates 14,16 ; con nement of the metal species in micropores might also limit mass transfers 15,17 .…”

Section: Introductionmentioning

confidence: 99%

Synergizing strong metal-support interactions and spatial confinement boosts dynamics of atomic nickel for hydrogenations

Jian

Huang

et al. 2020

Preprint

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Atomically dispersed metal catalysts maximize atom efficiency and display unique catalytic properties compared to regular metal nanoparticles. However, achieving high reactivity while still preserving high stability at high loadings remains as a grand challenge. Here we solve the challenge by synergizing strong metal-support interactions and spatial confinement, which enable to fabricate highly loaded (3.1 wt%), active and stable atomic Ni and dense atomic Cu grippers (8.1 wt%) on a graphitic C3N4 support. For semi-hydrogenation of acetylene in excess of ethylene, the fabricated catalyst shows 11 times higher activity than the atomic Ni alone, high ethylene selectivity (90%), and high stability against both sintering and coke formation for 350 h. Comprehensive microscopic and spectroscopic characterization and theoretical calculations reveal the active site of the bridging Ni confined in two hydroxylated Cu grippers, whose structure changes dynamically by breaking interfacial Ni-support bonds upon reactant adsorption and making these bonds upon product desorption. Such a dynamic effect confers high activity/selectivity and high stability, providing an avenue to rational design of efficient, stable, highly loaded, yet atomically dispersed catalysts.

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Confining isolated atoms and clusters in crystalline porous materials for catalysis

Cited by 267 publications

References 272 publications

Constructing the Support as a Microreactor and Regenerator for Highly Active and In Situ Regenerative Hydrogenation Catalyst

Constructing the Support as a Microreactor and Regenerator for Highly Active and In Situ Regenerative Hydrogenation Catalyst

Migration of Zeolite-Encapsulated Pt and Au Under Reducing Atmospheres

Synergizing strong metal-support interactions and spatial confinement boosts dynamics of atomic nickel for hydrogenations

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