Rotaxane or Pseudorotaxane? That Is the Question!

Ashton, Peter R.; Baxter, Ian; Fyfe, Matthew C. T.; Raymo, Françisco M.; Spencer, Neil; Stoddart, J. Fraser; White, and Andrew J. P.; Williams, David J.

doi:10.1021/ja9731276

Cited by 301 publications

(181 citation statements)

References 19 publications

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“…Compound 6 decomposes promptly (entry 1), 7 dissociated slowly (entry 2) and 8 dissociates at a rate too slow to measure (entry 3). The boronate moiety of 7 behaves as an end-capping group whose size is complementary to the DB24C8 cavity, [41][42][43][44] to prevent dissociation. On the other hand, the addition of triethylamine (Et 3 N) prompted the dissociation of 7 and 8 in comparison with the Et 3 N-free conditions (entries 4 and 5), probably due to not only a neutralization of the sec-ammonium moiety that disturbs the interaction between DB24C8 and axle component but also a dissociation of the dynamic covalent bond of boronate by humidity in the system.…”

Section: Resultsmentioning

confidence: 99%

Polymer architectures assisted by dynamic covalent bonds: synthesis and properties of boronate-functionalized polyrotaxane and graft polyrotaxane

Koyama

Suzuki

Asakawa

et al. 2011

Polym J

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Poly [2]rotaxane and graft polyrotaxane were synthesized from a mixture of poly(crown ether) (polyester-10 and polyisoxazole-13) as a trunk polymer, boronic-acid-terminated secondary ammonium salt 5 as an axle component, and diol as an end-capping group by pseudorotaxane formation and subsequent catalyst-free dehydrative bondage between the boronic acid and the diol moieties. Trunk polymers 10 and 13 were prepared by copolymerization of diol-or diyne-substituted dibenzo-24-crown-8-ether 9 or 11 and ditopic comonomers such as bifunctional acid dichloride and nitrile N-oxide. The use of the sufficiently bulky and stable homoditopic nitrile N-oxide 12 gave the high-molecular-weight isoxazole-containing poly(crown ether) 13 efficiently and without accidental penetration of the propagation end into the crown cavity, which would have caused gelation. The treatment of these poly(crown ether)s with boronic acid 5 in CH 2 Cl 2 gave the corresponding polypseudorotaxanes, and subsequent graftonto reaction with pinacol and a polymeric terminal diol gave poly[2]rotaxane and graft polyrotaxane. The chemical stability of these supramolecular architectures primarily depends on the bulkiness of the diol group as the end-capping moiety and the inherence originating from the dynamic covalent bond of boronate, as determined by detailed 1 H nuclear magnetic resonance study of model [2]rotaxanes 6-8 and the dissociation behavior of the polymers.

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Section: Resultsmentioning

confidence: 99%

Polymer architectures assisted by dynamic covalent bonds: synthesis and properties of boronate-functionalized polyrotaxane and graft polyrotaxane

Koyama

Suzuki

Asakawa

et al. 2011

Polym J

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“…The free energy of activation was observed to increase upon reducing the size of the cavity of the macrocycle and/or enlarging the bulk of the stoppers. Rotaxanes have also been synthesized [146][147][148] by slippage using other well-known recognition motifs. For example [146], the interaction of secondary dialkylammonium ions with commercially available dibenzo [24]crown-8.…”

Section: Synthesis Of Interlocked Molecules By Slippagementioning

confidence: 99%

“…Rotaxanes have also been synthesized [146][147][148] by slippage using other well-known recognition motifs. For example [146], the interaction of secondary dialkylammonium ions with commercially available dibenzo [24]crown-8. In 1997, Vögtle [148] reported the synthesis of the first amide-type rotaxane using the slippage approach.…”

Section: Synthesis Of Interlocked Molecules By Slippagementioning

confidence: 99%

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Templated Synthesis of Interlocked Molecules

Aricò

Badjić

Cantrill

et al. 2005

Topics in Current Chemistry

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195

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“…[1][2][3] More than two supramolecules can form molecular complex through selfassembly by coordination. 4 When the anion binding sites in each supramolecules form orthogonal complex, the binding sites provide three dimensional spaces.…”

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confidence: 99%