Multivariate Metal–Organic Frameworks as Multifunctional Heterogeneous Asymmetric Catalysts for Sequential Reactions

Xia, Qingchun; Li, Zi‐Jian; Tan, Chunxia; Gong, Wei; Cui, Yong

doi:10.1021/jacs.7b03113

Cited by 225 publications

(131 citation statements)

References 90 publications

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“…Indeed, the charming strategy of incorporating different synergistic functionalities into one crystalline network for various asymmetric transformations has long been pursued but remains a formidable synthetic challenge . A noteworthy development contributed by Cui and co‐workers is the fruitful synthesis of multivariate MOFs (MTV‐MOFs), where one, two, or three different enantiopure metallosalen‐based ligands M( L 5 ‐H 2 ) (M = Cu, VO, Cr, Mn, Fe, and Co) were strategically fixed and combined into a single framework. By varying the ratios of the different metallosalen ligands, five binary and two ternary MOFs were obtained with twofold interpenetrated isostructural networks corresponding to the single‐component MOFs, M10 − Cu ( Figure ).…”

Section: Asymmetric Catalysis Within the Chiral Confined Space Of Mofsmentioning

confidence: 99%

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Asymmetric Catalysis within the Chiral Confined Space of Metal–Organic Architectures

Cheng

et al. 2019

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The effective synthesis of chiral compounds in a highly enantioselective manner is obviously attractive. Inspired by the enzymatic reactions that occur in pocket‐like cavities with high efficiency and specificity, chemists are seeking to construct catalysts that mimic this key feature of enzymes. Recent progress in supramolecular coordination chemistry has shown that metal–organic cages (MOCs) and metal–organic frameworks (MOFs) with chiral confined cavities/pores may offer a novel platform for achieving asymmetric catalysis with high enantioselectivity. The inherent chiral confined microenvironment is considered to be analogous to the binding pocket of enzymes, and this pocket promotes enantioselective transformations. This work focuses on the recent advances in MOCs and MOFs with chiral confined spaces for asymmetric catalysis, and each section is separated into two parts based on how the chirality is achieved in these metal–organic architectures. A special emphasis is placed on discussing the relationship between the enantioselectivity and the confined spaces of the chiral functional MOCs and MOFs rather than catalytic chemistry. Finally, current challenges and perspectives are discussed. This work is anticipated to offer researchers insights into the design of sophisticated chiral confined space‐based metal–organic architectures for asymmetric catalysis with high enantioselectivity.

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Section: Asymmetric Catalysis Within the Chiral Confined Space Of Mofsmentioning

confidence: 99%

Section: Asymmetric Catalysis Within the Chiral Confined Space Of Mofsmentioning

confidence: 99%

Asymmetric Catalysis within the Chiral Confined Space of Metal–Organic Architectures

Cheng

et al. 2019

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“…In the meantime, the recently developed mixed component metal‐organic frameworks (MC‐MOFs) materials by integrating two or more different components into one skeleton render MOFs with different functional sites thus providing these porous materials access to various utilities . Examples of MC‐MOFs including mixed linker or multivariate, mixed metal, core‐shell, and surface modified MOFs, showed better porosity, absorption, stability, catalytic performance or other characteristics compared with the single component MOFs . Among these MC‐MOF materials, mixed metal MOFs have attracted much attention for diverse applications such as catalysis, separation, and others due to their improved properties, especially pointing to mixed metal zeolitic imidazolate frameworks (ZIFs) .…”

Section: Introductionmentioning

confidence: 99%

Controlling Metal Ion Counter Diffusion in Confined Spaces for In Situ Growth of Mixed Metal MOF Membranes for Gas Separation

et al. 2019

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The development of facile, versatile strategies for the fabrication of mixed component metal‐organic framework (MOF) membranes is highly desired, but still very challenging due to the difficulty in controlling crystal growth rates of every single component in a specific confined space. It is difficult to adjust the formation of multicomponent MOF membrane in a controlled manner using conventional approaches such as secondary growth methods. Herein, we present a facile strategy that prepares the mixed metal zeolitic imidazolate framework (ZIF) membranes in situ in a confined space with nanostructure arrays under hydrothermal conditions using the counter diffusion mechanism. The counter diffusion of different metal ions from both the homogeneous bulk solution and the solid metal oxide nanostructure grown on substrate leads to the specific effective reaction zone by encountering with linker molecules at the interface. Subsequently, nucleation and crystal growth generate the continuous mixed metal MOF membranes. With this approach, a variety of mixed metal ZIF membranes were synthesized on different kinds of substrates. The prepared membranes exhibited good sieving effect to H2 and heavier gas molecules during both single and mixed gas permeation tests. This work opens a fresh avenue for the synthesis of mixed component MOF membranes, and the counter diffusion effect can be intentionally adopted to the design and fabrication of selective mixed metal MOF membrane on various supports.

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“…Thea bove notable new bands of MIL-101(Cr)-FLP-H 2 further suggest the existence of the FLP-H 2 inside the MOF. [12] Interestingly,f or the substrate 7a,b oth imine and alkene double bonds were reduced in the case of homogeneous FLP,and no 7b can be observed after the catalytic reaction. TheCr(2p 1/2 )and Cr (2p 3/2 )peaks of MIL-101(Cr)-FLP-H 2 are shifted by around 0.58-2 eV toward higher binding energies,c ompared to those of MIL-101(Cr).…”

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“…It remains as ignificant challenge for FLP catalysts to selectively hydrogenate a,b-unsaturated organic compounds to afford the relevant olefin product especially in heterogeneous systems. [11] Thediverse yet tunable features of MOFs [12] make them an efficient platform to manipulate heterogeneous catalysts for various organic transformations that traditional porous materials simply cannot provide. [11] Thediverse yet tunable features of MOFs [12] make them an efficient platform to manipulate heterogeneous catalysts for various organic transformations that traditional porous materials simply cannot provide.…”

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Promoting Frustrated Lewis Pairs for Heterogeneous Chemoselective Hydrogenation via the Tailored Pore Environment within Metal–Organic Frameworks

et al. 2019

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Frustrated Lewis pairs (FLPs) have recently been advanced as efficient metal-free catalysts for catalytic hydrogenation, but their performance in chemoselective hydrogenation, particularly in heterogeneous systems,h as not yet been achieved. Herein, we demonstrate that, via tailoring the pore environment within metal-organic frameworks (MOFs), FLPs not only can be stabilized but also can develop interesting performance in the chemoselective hydrogenation of a,bunsaturated organic compounds,w hichc annot be achieved with FLPs in ah omogeneous system. Using hydrogen gas under moderate pressure,the FLP anchored within aMOF that features open metal sites and hydroxy groups on the pore walls can serve as ah ighly efficient heterogeneous catalyst to selectively reduce the imine bond in a,b-unsaturated imine substrates to affordunsaturated amine compounds.

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Multivariate Metal–Organic Frameworks as Multifunctional Heterogeneous Asymmetric Catalysts for Sequential Reactions

Cited by 225 publications

References 90 publications

Asymmetric Catalysis within the Chiral Confined Space of Metal–Organic Architectures

Asymmetric Catalysis within the Chiral Confined Space of Metal–Organic Architectures

Controlling Metal Ion Counter Diffusion in Confined Spaces for In Situ Growth of Mixed Metal MOF Membranes for Gas Separation

Promoting Frustrated Lewis Pairs for Heterogeneous Chemoselective Hydrogenation via the Tailored Pore Environment within Metal–Organic Frameworks

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