AI Article Synopsis
- Diamine reagents were used to functionalize a [2]rotaxane building block featuring a pentafluorophenyl ester stopper, resulting in an intermediate with a terminal amine.
- Depending on reaction conditions, the intermediate can either dissociate and form a [2]rotaxane or stabilize into a [3]rotaxane when using mechanochemical, solvent-free methods.
- Variable temperature NMR and density functional theory calculations were employed to analyze the shuttling motions of the pillar[5]arene subunit within these rotaxanes.
Article Abstract
Diamine reagents have been used to functionalize a [2]rotaxane building block bearing an activated pentafluorophenyl ester stopper. Upon a first acylation, an intermediate host-guest complex with a terminal amine function is obtained. Dissociation of the intermediate occurs in solution and acylation of the released axle generates a [2]rotaxane with an elongated axle subunit. In contrast, the corresponding [3]rotaxane can be obtained if the reaction conditions are appropriate to stabilize the inclusion complex of the mono-amine intermediate and the pillar[5]arene. This is the case when the stopper exchange is performed under mechanochemical solvent-free conditions. Alternatively, if the newly introduced terminal amide group is large enough to prevent the dissociation, the second acylation provides exclusively a [3]rotaxane. On the other hand, detailed conformational analysis has been also carried out by variable temperature NMR investigations. A complete understanding of the shuttling motions of the pillar[5]arene subunit along the axles of the rotaxanes reported therein has been achieved with the help of density functional theory calculations.
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Article Synopsis
- Diamine reagents were used to functionalize a [2]rotaxane building block featuring a pentafluorophenyl ester stopper, resulting in an intermediate with a terminal amine.
- Depending on reaction conditions, the intermediate can either dissociate and form a [2]rotaxane or stabilize into a [3]rotaxane when using mechanochemical, solvent-free methods.
- Variable temperature NMR and density functional theory calculations were employed to analyze the shuttling motions of the pillar[5]arene subunit within these rotaxanes.
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