Solvent-Selective Reactions of Alkyl Iodide with Sodium Azide for Radical Generation and Azide Substitution and Their Application to One-Pot Synthesis of Chain-End-Functionalized Polymers

Solvent-Selective Reactions of Alkyl Iodide with Sodium Azide for Radical Generation and Azide Substitution and Their Application to One-Pot Synthesis of Chain-End-Functionalized Polymers

Herein, a new reaction of an alkyl iodide (R–I) with an azide anion (N3–) to reversibly generate the corresponding alkyl radical (R•) is reported. Via this new reaction, N3– was used as an efficient catalyst in living radical polymerization, yielding a well-defined polymer–iodide. A particularly int...

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Bibliographic Details
Main Authors: Wang, Chen-Gang, Goto, Atsushi
Other Authors: School of Physical and Mathematical Sciences
Format: Article
Language:English
Published: 2018
Subjects:
End-functionalized Polymers
Selective Reactions
Online Access:https://hdl.handle.net/10356/87091
http://hdl.handle.net/10220/44315
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Institution: Nanyang Technological University
Language: English
Description
Summary:Herein, a new reaction of an alkyl iodide (R–I) with an azide anion (N3–) to reversibly generate the corresponding alkyl radical (R•) is reported. Via this new reaction, N3– was used as an efficient catalyst in living radical polymerization, yielding a well-defined polymer–iodide. A particularly interesting finding was the solvent selectivity of this reaction; namely, R–I and N3– generated R• in nonpolar solvents, while the substitution product R–N3 was generated in polar solvents. Exploiting this unique solvent selectivity, a one-pot synthesis of polymer–N3 was attained. N3– was first used as a catalyst for living radical polymerization in a nonpolar solvent to produce a polymer–iodide and was subsequently used as a substitution agent in a polar solvent by simply adding the polar solvent, thereby transforming the polymer–iodide to polymer–N3 in one pot. This one-pot synthesis was further applied to obtain N3-chain-end-functionalized polymer brushes on the surface, uniquely controlling the N3 coverage (number density). Using the chain-end N3, the obtained linear and brush polymers were connected to functional molecules via an azide–alkyne click reaction. The attractive features of this system include facile operation, access to unique polymer designs, and no requirement for using excess NaN3. In addition to N3–, thiocyanate (−SCN) and cyanate (−OCN) anions were also studied.

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