Engineering of Yolk/Core–Shell Structured Nanoreactors for Thermal Hydrogenations

Ye, Runping; Wang, Xinyao; Price, Cameron Alexander Hurd; Liu, Xiaoyan; Yang, Qihua; Jaroniec, Mietek; Liu, Jian

doi:10.1002/smll.201906250

Cited by 65 publications

(46 citation statements)

References 156 publications

(196 reference statements)

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“…In addition to core-shell structure, the yolk-shell nanostructures have great potential for catalysis, due to their multifunctions composed of nanoparticle cores, microporous shells and cavities. [41][42][43][44][45][46][47][48] The MOFs shell can finely control the selective mass transfer of reactants. Only reactants with molecular � pore size are perimitted to diffuse into the cavity.…”

Section: Mnps@mofsmentioning

confidence: 99%

Nanospace Engineering of Metal‐Organic Frameworks for Heterogeneous Catalysis

Wang

Yang

et al. 2021

ChemNanoMat

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The structural advantages of metal-organic frameworks (MOFs) can facilitate wide applications in the field of catalysis, including oxidation, hydrogenation, acetalization, transesterification, catalytic cracking, and so on. The efficiency of catalysis is closely related to the synergy between active center, auxiliary center, and microenvironment. Researchers can customize MOFs according to the needs of catalytic reactions, and many strategies were established for boosting catalytic performance. In this review, we aim to summarize and illustrate recent progress in the nanospace engineering of MOFs. Generally, MOFs were engineered mainly from the following aspects: 1) Regulation of pore size, including micropores, mesopores, and macropores. 2) Engineering of encapsulated active species, such as metal nanoparticles, quantum dots, polyoxometalates, enzymes, etc. 3) Engineering of MOFs morphology from zero dimension to three-dimension. 4) Controllable integration of MOFs with multi-strategies. 5) Construction of multivariate MOFs via introducing multiple or mixed organic functional groups into the existing framework. Besides, for further low cost and practical applications, challenges for MOFs as green and sustainable catalysts are also discussed.

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Section: Mnps@mofsmentioning

confidence: 99%

Nanospace Engineering of Metal‐Organic Frameworks for Heterogeneous Catalysis

Wang

Yang

et al. 2021

ChemNanoMat

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“…Catalysts that use this morphology are still emerging as the structures' benefits are better explored and understood [24,[272][273][274][275][276][277]; a key benefit offered is that of the confinement effect. This phenomenon is often under-discussed for these materials as it is still not fully understood, but is divided into two types: quantum and spatial, with the difference between the two explored in more detail elsewhere [278][279][280].…”

Section: Base Metal Catalystsmentioning

confidence: 99%

“…This structure with base metals is beginning to find increasing use within hydrogenation reactions [24] (Fig. 13); recent work has found Ni@UiO-66 to be particularly effective for the Sabatier reaction.…”

Section: Application Towards Co 2 Hydrogenationmentioning

confidence: 99%

“…This review aims to present the current situation of catalyst development in the field of thermal CO 2 utilization and deactivation resistance, demonstrating that the SMN catalysts are still the most widely applied morphology despite becoming increasingly complex to solve the problems of deactivation and reactive longevity; there are much simpler answers to these questions, such as material encapsulation. Catalyst development in this way has been reviewed previously [21][22][23][24], though these are either focussed entirely or heavily on documenting the synthetic pathways, in addition to the final application. The encapsulated morphologies are largely summarised in two varieties: core@shell and yolk@shell, the former is the encapsulation of a core particle by an outer layer (such as SiO 2 or Al 2 O 3 ), while the latter follows the same structure but possesses a void space between the core and the shell, giving rise to a fascinating set of properties that are widely known as the confinement effect, which is covered later.…”

Section: Introductionmentioning

confidence: 99%

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Engineering heterogenous catalysts for chemical CO2 utilization: Lessons from thermal catalysis and advantages of yolk@shell structured nanoreactors

Price

Reina

Liu

2021

Journal of Energy Chemistry

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“…Nanoreactors can be identified as covalent systems like dendrimers and nanogels and self‐assembled nanoreactors like micelles and polymeric vesicles. [ 35 ] Recent reviews [ 36–38 ] have illustrated the advances in the synthesis and application of nanoreactors. A comprehensive review on the hollow nano‐ and microstructures was presented by Prieto et al, [ 39 ] summarizing the synthesis methods and applications of hollow nano‐ and microstructures as bio‐, electro‐, and photocatalysts.…”

Section: Introductionmentioning

confidence: 99%

Introducing rGO@Fe₃O₄@Ni as an efficient magnetic nanocatalyst for the synthesis of tetrahydrobenzopyranes via multicomponent coupling reactions of dimedone, malononitrile, and aromatic aldehydes

Esmati

Zeynizadeh

2021

Applied Organom Chemis

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In this study, the synthesis and characterization of the modified GO and rGO@Fe3O4@Ni composite systems were investigated. Fourier‐transform infrared spectroscopy (FT‐IR), scanning electron microscopy (SEM), transmission electron microscopy (TEM), energy‐dispersive x‐ray spectroscopy (EDX), x‐ray powder diffraction (XRD), vibrating sample magnetometer (VSM), Brunauer–Emmett–Teller (BET) analysis, thermogravimetric analysis (TGA), and inductively coupled plasma optical emission spectroscopy (ICP‐OES) were employed to characterize the prepared nanomaterials. Also, catalytic activities of GO, rGO@Fe3O4, rGO@Ni, and rGO@Fe3O4@Ni were compared, and rGO@Fe3O4@Ni as the efficient magnetic nanocatalyst was applied to expedite the multicomponent coupling reactions (MCRs) of dimedone, malononitrile, and structurally diverse aromatic aldehydes to prepare tetrahydrobenzopyranes. All reactions were fulfilled efficiently in deionized water under reflux conditions. In addition, sustainability of the nanocatalyst was examined for five consecutive reaction cycles without the significant loss of its catalytic activity.

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Engineering of Yolk/Core–Shell Structured Nanoreactors for Thermal Hydrogenations

Cited by 65 publications

References 156 publications

Nanospace Engineering of Metal‐Organic Frameworks for Heterogeneous Catalysis

Nanospace Engineering of Metal‐Organic Frameworks for Heterogeneous Catalysis

Engineering heterogenous catalysts for chemical CO2 utilization: Lessons from thermal catalysis and advantages of yolk@shell structured nanoreactors

Introducing rGO@Fe₃O₄@Ni as an efficient magnetic nanocatalyst for the synthesis of tetrahydrobenzopyranes via multicomponent coupling reactions of dimedone, malononitrile, and aromatic aldehydes

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Engineering of Yolk/Core–Shell Structured Nanoreactors for Thermal Hydrogenations

Cited by 65 publications

References 156 publications

Nanospace Engineering of Metal‐Organic Frameworks for Heterogeneous Catalysis

Nanospace Engineering of Metal‐Organic Frameworks for Heterogeneous Catalysis

Engineering heterogenous catalysts for chemical CO2 utilization: Lessons from thermal catalysis and advantages of yolk@shell structured nanoreactors

Introducing rGO@Fe3O4@Ni as an efficient magnetic nanocatalyst for the synthesis of tetrahydrobenzopyranes via multicomponent coupling reactions of dimedone, malononitrile, and aromatic aldehydes

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Product

Resources

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Introducing rGO@Fe₃O₄@Ni as an efficient magnetic nanocatalyst for the synthesis of tetrahydrobenzopyranes via multicomponent coupling reactions of dimedone, malononitrile, and aromatic aldehydes