Acid Catalysis in Basic Solution: A Supramolecular Host Promotes Orthoformate Hydrolysis

Pluth, Michael D.; Bergman, Robert G.; Raymond, Kenneth N.

doi:10.1126/science.1138748

Cited by 740 publications

(442 citation statements)

References 32 publications

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“…26 The same types of size selectivities have been observed when using the assembly as a catalyst for the hydrolysis of acid-sensitive substrates. 12,28 In the hydrolysis of orthoformates, only substrates smaller than tri-n-pentyl orthoformate are able to enter the assembly to undergo hydrolysis. Similarly, for the hydrolysis of acetals, small acetals are readily hydrolyzed inside of the assembly whereas larger acetals are not.…”

Section: Background Of the M 4 L 6 Assemblymentioning

confidence: 99%

Structural Consequences of Anionic Host−Cationic Guest Interactions in a Supramolecular Assembly

et al. 2008

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The molecular structure of the spontaneously assembled supramolecular cluster [M4L6] n− has been explored with different metals (M = GaIII, FeIII, TiIV) and different encapsulated guests (NEt4 +, BnNMe3 +, Cp2Co+, Cp*2Co+) by X-ray crystallography. While the identity of the metal ions at the vertices of the M4L6 structure is found to have little effect on the assembly structure, encapsulated guests significantly distort the size and shape of the interior cavity of the assembly. Cations on the exterior of the assembly are found to interact with the assembly through either π−π, cation−π, or CH−π interactions. In some cases, the exterior guests interact with only one assembly, but cations with the ability to form multiple π−π interactions are able to interact with adjacent assemblies in the crystal lattice. The solvent accessible cavity of the assembly is modeled using the rolling probe method and found to range from 253−434 Å3, depending on the encapsulated guest. On the basis of the volume of the guest and the volume of the cavity, the packing coefficient for each host−guest complex is found to range from 0.47−0.67.

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Section: Background Of the M 4 L 6 Assemblymentioning

confidence: 99%

Structural Consequences of Anionic Host−Cationic Guest Interactions in a Supramolecular Assembly

et al. 2008

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“…For example, the acid-catalyzed hydrolysis of acetals and orthoformates is catalyzed by 1 in basic solution by lowering the pK a of the encapsulated substrate. 29 Several encapsulated transition metal complexes can participate in stoichiometric and catalytic organometallic reactions in which 1 imposes strict limits on the size and shape of substrates that will react. [30][31][32] Pericyclic reactions are popular targets in supramolecular catalysis because encapsulation by itself can enforce the geometries necessary for enhanced reactivity, even in the absence of accelerating functional groups within the cavity.…”

Section: Introductionmentioning

confidence: 99%

Aza Cope Rearrangement of Propargyl Enammonium Cations Catalyzed By a Self-Assembled “Nanozyme”

et al. 2008

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“…49 We have recently reported the ability of 1 to greatly favor the protonated form of encapsulated substrates such as amines, with pK a shifts of up to 4.5 pK a units, and have exploited this stabilization for the catalysis of orthoformates and acetals in basic solution. 44,50 Herein we expand upon our initial report of orthoformate hydrolysis to include a detailed study of the mechanism of hydrolysis in 1. …”

Section: Introductionmentioning

confidence: 99%

Spin Equilibria in Monomeric Manganocenes: Solid-State Magnetic and EXAFS Studies

et al. 2009

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A water-soluble self-assembled supramolecular host molecule catalyzes the hydrolysis of orthoformates in basic solution. Comparison of the rate constants of the catalyzed and uncatalyzed reactions for hydrolysis displays rate accelerations of up to 3900 for tri-n-propyl orthoformate. Kinetic analysis shows that the mechanism of hydrolysis with the supramolecular host obeys the Michaelis-Menten model.Mechanistic studies, including 13 C-labeling experiments, revealed that the resting state of the catalytic system is the neutral substrate encapsulated in the host. Activation parameters for the k cat step of the reaction revealed that upon encapsulation in the assembly, the entropy of activation becomes more negative in contrast to the uncatalyzed reaction. Furthermore, solvent isotope effects reveal a normal k(H 2 O)/k(D 2 O) = 1.6, confirming that proton transfer is occurring in the transition state and is rate limiting in the catalyzed reaction. In comparison to the uncatalyzed reaction, which operates by an A-1 mechanism in which the decomposition of the protonated substrate is rate limiting, the encapsulated reaction proceeds through an A-S E 2 mechanism in which proton transfer from protonated water to the substrate is rate limiting.

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Acid Catalysis in Basic Solution: A Supramolecular Host Promotes Orthoformate Hydrolysis

Cited by 740 publications

References 32 publications

Structural Consequences of Anionic Host−Cationic Guest Interactions in a Supramolecular Assembly

Structural Consequences of Anionic Host−Cationic Guest Interactions in a Supramolecular Assembly

Aza Cope Rearrangement of Propargyl Enammonium Cations Catalyzed By a Self-Assembled “Nanozyme”

Spin Equilibria in Monomeric Manganocenes: Solid-State Magnetic and EXAFS Studies

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