Nanostructured Polymer Duplexes via the Covalent Casting of 1-Dimensional H-Bonding Motifs:  A New Strategy for the Self-Assembly of Macromolecular Precursors

Archer, Eric A.; Goldberg, Noah T.; Lynch, and Vincent; Krische, Michael J.

doi:10.1021/ja000777s

Cited by 49 publications

(27 citation statements)

References 24 publications

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“…Having prepared discrete duplex oligomers, the preparation of polymeric materials was desired. Diol‐linked aminotriazine dimer 9 undergoes condensation polymerization with homopiperazine, which may be viewed as a conformationally constrained 1,3‐diamine 1a. The polymer backbone contains alternating 1,3‐diol and 1,3‐diamine linkages.…”

Section: Discussionmentioning

confidence: 99%

The Covalent Casting of One-Dimensional Hydrogen Bonding Motifs: Toward Oligomers and Polymers of Predefined Topography

2001

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The covalent casting of noncovalent architectures serves to define large covalent constructs that express well-defined modes of aggregation. In the case of one-dimensional hydrogen-bonding motifs, covalent casting yields molecular strands that adopt a duplex mode of aggregation. The effectiveness of this design principle is illustrated through the casting of the aminotriazine hydrogen-bonding motif. These studies have led to the conception of a new family of topographically defined oligomers, which, akin to DNA, self-assemble in the form of a duplex through the action of interstrand hydrogen bonds.

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Section: Discussionmentioning

confidence: 99%

The Covalent Casting of One-Dimensional Hydrogen Bonding Motifs: Toward Oligomers and Polymers of Predefined Topography

2001

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“…Very recently, Krische and co‐workers used similar template effects in the covalent casting of one‐dimensional H‐bonding motifs for the preparation of duplex molecular strands 336…”

Section: Templated Synthesismentioning

confidence: 99%

Noncovalent Synthesis Using Hydrogen Bonding

Prins

Reinhoudt

Timmerman

2001

Angew. Chem. Int. Ed.

1,252

765

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Hydrogen bonds are like human beings in the sense that they exhibit typical grouplike behavior. As an individual they are feeble, easy to break, and sometimes hard to detect. However, when acting together they become much stronger and lean on each other. This phenomenon, which in scientific terms is called cooperativity, is based on the fact that “1+1 is more than 2”. By using this principle, chemists have developed a wide variety of chemically stable structures that are based on the reversible formation of multiple hydrogen bonds. More than 20 years of fundamental studies on these phenomena have gradually developed into a new discipline within the field of organic synthesis, and is nowadays called “noncovalent synthesis”. This review describes noncovalent synthesis based on the reversible formation of multiple hydrogen bonds. Starting with a thorough description of what the “hydrogen bond” really is, it guides the reader through a variety of bimolecular and higher order assemblies and exemplifies the general principles that determine their stability. Special focus is given to reversible capsules based on hydrogen‐bonding interactions that exhibit interesting encapsulation phenomena. Furthermore, the role of hydrogen‐bond formation in self‐replicating processes is actively discussed, and finally the review briefly summarizes the development of novel materials (nanotubes, liquid crystals, polymers, etc.) and principles (dynamic libraries) that recently have emanated from this intriguing field of research.

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“…[336] [51] 1/2 k b ), wobei k a und k b die Geschwindigkeitskonstanten für den autokatalytischen bzw. [336] [51] 1/2 k b ), wobei k a und k b die Geschwindigkeitskonstanten für den autokatalytischen bzw.…”

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