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This microreview outlines recent advances on the synthesis and self-assembly of polyphosphazene diblock copolymers, a class of versatile polymers (Multi-Tool) able to generate a great variety of different well-defined nanomorphologies. Particular focus is placed on the synthesis of linear block copolymers composed of two polyphosphazene chains (PP-b-PP′), or hybrid polymers combining one PP chain with a non- [a] 2484 Gabino A. Carriedo (Ph D in 1981) is Full-time Professor of Inorganic Chemistry in the University of Oviedo since 1989. His research interest in synthetic chemistry has included coordination and organometallic chemistry, electrochemistry and polymer chemistry. Since 1995 he has focused in designed syntheses of phosphazene polymers and their chemical derivatization. (2012) developing new synthetic methodologies in organic chemistry by means of organometallic carbene reagents under the supervision of Prof. J. Barluenga and Prof. J. Flórez. After, she moved to the group of D. Dixon (Oxford) to explore new catalytic asymmetric methodologies. She returned to the University of Oviedo in 2015 as Post-doctoral research assistant. Nowadays, her research is focused on the synthesis and self-assembly of new material based on polyphosphazene polymers. 2488 Scheme 4. Synthesis of linear polyphosphazene diblock copolymers 28-35 by sequential living cationic polymerization of phosphoranimines of type (X)(R 1 )(R 2 )P=N-SiMe 3 over living chains of 1[PCl 6 ]. Scheme 5. Sequential living polymerization of phosphoranimine 36 by using active end-groups of polyphosphazene 17 as initiators. The synthesis of BCP 37 is suggested in ref. 47. methodologies afforded the PP-b-PS copolymers with moderately good yields (< 60 %) and polydispersities (< 1.3). Scheme 10. Synthetic routes to polyphosphazene-b-polystyrene, PP-b-PS, via macromolecular coupling of telechelic (PS) n -P(R) 2 = N-SiMe 3 , 53 and 54, with an end-capped poly(dichlorophosphazene) 55 (Ec. c). Raquel de la Campa was born in Cangas del Narcea (Asturias, Spain) in 1981. He obtained his PhD at the University of OviedoRecently, our group developed a very convenient synthesis for linear hybrid PP-b-PS block copolymers (Scheme 11). [63] Using the lithiated-phosphine 56 as initiator, the anionic polymerization of styrene gave the telechelic polystyrene 57 (PS m -PPh 2 ) after quenching the reaction with Cl-SiMe 3 . The chlorination of Scheme 11. Synthetic routes to polyphosphazene-b-polystyrene, PP-b-PS (60), via lithiated-phosphine initiator 56, and macromolecular initiator 58.2492 57 led to PS m -PPh 2 Cl 2 (58) having -PPh 2 Cl 2 end-groups that initiate the polymerization of Cl 3 P=N-SiMe 3 (6) producing the block copolymer [N=PCl 2 ] n -PS m (59). The macromolecular substitution of the chlorine atoms by -OCH 2 CF 3 groups yielded the block copolymer [N=P(OCH 2 CF 3 ) 2 ] n -PS m (60) having crystalline PP blocks. This synthetic methodology afforded the hybrid PP-b-PS block copolymer in 70 % yield and with narrower polydispersities (PDI = 1.2) than those of the...
This microreview outlines recent advances on the synthesis and self-assembly of polyphosphazene diblock copolymers, a class of versatile polymers (Multi-Tool) able to generate a great variety of different well-defined nanomorphologies. Particular focus is placed on the synthesis of linear block copolymers composed of two polyphosphazene chains (PP-b-PP′), or hybrid polymers combining one PP chain with a non- [a] 2484 Gabino A. Carriedo (Ph D in 1981) is Full-time Professor of Inorganic Chemistry in the University of Oviedo since 1989. His research interest in synthetic chemistry has included coordination and organometallic chemistry, electrochemistry and polymer chemistry. Since 1995 he has focused in designed syntheses of phosphazene polymers and their chemical derivatization. (2012) developing new synthetic methodologies in organic chemistry by means of organometallic carbene reagents under the supervision of Prof. J. Barluenga and Prof. J. Flórez. After, she moved to the group of D. Dixon (Oxford) to explore new catalytic asymmetric methodologies. She returned to the University of Oviedo in 2015 as Post-doctoral research assistant. Nowadays, her research is focused on the synthesis and self-assembly of new material based on polyphosphazene polymers. 2488 Scheme 4. Synthesis of linear polyphosphazene diblock copolymers 28-35 by sequential living cationic polymerization of phosphoranimines of type (X)(R 1 )(R 2 )P=N-SiMe 3 over living chains of 1[PCl 6 ]. Scheme 5. Sequential living polymerization of phosphoranimine 36 by using active end-groups of polyphosphazene 17 as initiators. The synthesis of BCP 37 is suggested in ref. 47. methodologies afforded the PP-b-PS copolymers with moderately good yields (< 60 %) and polydispersities (< 1.3). Scheme 10. Synthetic routes to polyphosphazene-b-polystyrene, PP-b-PS, via macromolecular coupling of telechelic (PS) n -P(R) 2 = N-SiMe 3 , 53 and 54, with an end-capped poly(dichlorophosphazene) 55 (Ec. c). Raquel de la Campa was born in Cangas del Narcea (Asturias, Spain) in 1981. He obtained his PhD at the University of OviedoRecently, our group developed a very convenient synthesis for linear hybrid PP-b-PS block copolymers (Scheme 11). [63] Using the lithiated-phosphine 56 as initiator, the anionic polymerization of styrene gave the telechelic polystyrene 57 (PS m -PPh 2 ) after quenching the reaction with Cl-SiMe 3 . The chlorination of Scheme 11. Synthetic routes to polyphosphazene-b-polystyrene, PP-b-PS (60), via lithiated-phosphine initiator 56, and macromolecular initiator 58.2492 57 led to PS m -PPh 2 Cl 2 (58) having -PPh 2 Cl 2 end-groups that initiate the polymerization of Cl 3 P=N-SiMe 3 (6) producing the block copolymer [N=PCl 2 ] n -PS m (59). The macromolecular substitution of the chlorine atoms by -OCH 2 CF 3 groups yielded the block copolymer [N=P(OCH 2 CF 3 ) 2 ] n -PS m (60) having crystalline PP blocks. This synthetic methodology afforded the hybrid PP-b-PS block copolymer in 70 % yield and with narrower polydispersities (PDI = 1.2) than those of the...
This mini‐review gives a short summery of the chain‐end chemistry of polysilanes, notably that leading to block copolymers. The anionic polymerisations of cyclotetrasilanes or ‘masked’ disilenes naturally lend themselves to the formation of polysilane‐containing copolymers. A more robust, if less controlled, method results from the Wurtz‐type reductive coupling reaction that yields polysilanes with silyl chloride chain‐ends which are extremely sensitive to nucleophilic substitution. These may be used with appropriately functionalised polymers (such as polyisoprene or poly(ethylene oxide)) to prepare multiblock copolymers, or with functionalised groups designed as initiating centres for subsequent controlled reversible deactivation radical polymerisations (such as atom transfer radical polymerisation). Copyright © 2009 Society of Chemical Industry
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