Anionic-Cationic Block Copolymerisation

Within the context of stable carbenium salts initiatron, we already examined a very interesting and successful study on the block copolymeriation of a-methylstyrene with cyclopentadiene performed by Vairon and Villesange (see Sect. V-A-4-b). The preparation of the product required three basic operations (i) the living anionic polymerisation of a-methylstyrene to give monodisperse macromolecules, (ii) transformation of their end groups into stable carbocationic moieties, and (iii) initiation of the polymerisation of cyclopentadiene from these active ends under conditions of minimal transfer and termination reactions. Thus, the macroinitiators in the second polymerisation were generated by a controlled anionic polymerisation and allowed tiie synthesis of a triblock near-isomolecular copolymer. 

A similar principle was followed by Burgess et when they discussed the 

The above ideas open promising avenues for the preparation of block copolymers. 

A major problem of cour remains, namely finding the appropriate conditions for the effective living polymerisation of the second monomer onto the cationic macroinitiators. The only olefin approaching this behaviour which has been use to the present is cyclopentadiene. Among cyclic n-donor monomers the choice is wider, but these considerations are outside the scope of the present review. 

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We have some evidence that this theoretical problem is a genuine limitation in the case of a quaternised styrenic monomer which is block copolymerised with NaVBA. This problem can be circumvented in two ways. Firstly, the polymerisation sequence can be simply reversed so that the longer block is synthesised first. If this is the quaternised block, the resulting copolymer cannot exhibit an isoelectric point because the major block is permanently cationic, thus no charge compensation can occur. On the other hand, if the longer block is anionic, then addition of HCl will protonate the acidic monomer residues and at some point an isoelectric point will be attained (unless the acidic block is strongly acidic, e.g. 4-styrenesulfonic acid). 

The present volume is particularly concerned with the use of the different modes of controlled radical polymerisation for the preparation of copolymers such as random copolymers, linear block copolymers, as well as graft copolymers and star-shaped copolymers. It also presents the combination of controlled radical polymerisation with non-controlled radical copolymerisation, cationic and anionic polymerisation,both of vinyl monomers and cyclic monomers, and ringopening metathesis polymerisation. 

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