Functional cavitands: Chemical reactivity in structured environments

Purse, Byron W.; Rebek, Julius

doi:10.1073/pnas.0501731102

Cited by 156 publications

(72 citation statements)

References 49 publications

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“…[5] The most fascinating feature of top-open resorcin [4]arene cavitands is their ability to adopt two spatially well-defined conformations: an expanded "kite" form and a contracted "vase" form. While various methods have been employed to study the conformational properties of cavitands, [6] the most convenient one is 1 H NMR spectroscopy.…”

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confidence: 99%

“…Since the preparation of the first quinoxaline-bridged resorcin [4]arene cavitand by Cram and co-workers in 1982, [1] numerous derivatives with various structures and functions have been prepared and employed as switches, [2] receptors and sensors, [3] catalysts, [4] and molecular hosts. [5] The most fascinating feature of top-open resorcin [4]arene cavitands is their ability to adopt two spatially well-defined conformations: an expanded "kite" form and a contracted "vase" form.…”

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confidence: 99%

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Quinone‐Based, Redox‐Active Resorcin[4]arene Cavitands

Pochorovski¹,

Boudon²,

Gisselbrecht³

et al. 2011

Angew Chem Int Ed

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Quinone‐Based, Redox‐Active Resorcin[4]arene Cavitands

Pochorovski¹,

Boudon²,

Gisselbrecht³

et al. 2011

Angew Chem Int Ed

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“…The development in supramolecular chemistry has evolved such that several synthetic systems are now available to also study the reactivity in confined nano-spaces, such as the well-defined cavities of metal-organic frameworks, and (supra)molecular capsules. It has been demonstrated by the pioneering work of Sanders and co-workers 15 , Rebek and co-workers [16][17][18][19] , Fujita and co-workers 20 and Raymond and co-workers 21 that organic reactions that occur in such restricted environments can result in unusual selectivities and rate enhancements. These all are elegant examples in which it has been demonstrated that the activity or selectivity of organic reactions can be controlled by nano-capsules.…”

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confidence: 99%

Capsule-controlled selectivity of a rhodium hydroformylation catalyst

et al. 2013

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Chemical processes proceed much faster and more selectively in the presence of appropriate catalysts, and as such the field of catalysis is of key importance for the chemical industry, especially in light of sustainable chemistry. Enzymes, the natural catalysts, are generally orders of magnitude more selective than synthetic catalysts and a major difference is that they take advantage of well-defined cavities around the active site to steer the selectivity of a reaction via the second coordination sphere. Here we demonstrate that such a strategy also applies for a rhodium catalyst; when used in the hydroformylation of internal alkenes, the selectivity of the product formed is steered solely by changing the cavity surrounding the metal complex. Detailed studies reveal that the origin of the capsule-controlled selectivity is the capsule reorganization energy, that is, the high energy required to accommodate the hydride migration transition state, which leads to the minor product.

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“…[6] However, only rare examples describe the endo-complexation of organic guests by calix [4]arenes because of the smallness of their cavity. [7] On the other hand, the larger calix [6]arenes are more difficult to constrain into a given conformation, since these oligomers display a higher flexibility because of the facile "through the annulus" ring inversion of their aromatic units.…”

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confidence: 99%