Mechanism of formation of cyclic species in cationic ring-opening polymerization of cyclodimethylsiloxanes

A general feature of the cationic polymerization of all cyclodimethylsiloxanes is the formation of various cyclic products (cyclics) together with that of a linear high polymer. However, the types of cyclics as well as their rate of formation may vary considerably according to the number x of D units ((CH₃)₂SiO units) in the monomer. The case of initiation by trifluoromethanesulfonic (triflic) acid in methylene chloride solution at 20°C has been particularly studied. With D₄, D₅, D₆ and D₇, for which the polymerization rate increases with the size of the ring, all types of cycles D_x are formed in relative amount decreasing with their size (D₇] < D₆] < D₅] < D₄]). The high polymer final concentration and molecular weight are independent from triflic acid concentration. This may result from a polymerization-depolymerization reaction, involving all the cyclics formed by back-biting reactions occurring with silyl triflates activated by the acid, and leading finally to an equilibrium. The situation with D₃ is completely different. The high polymer (HP) and the cyclics (D_3x multiples of D₃ like D₆, D₉, …) are formed simultaneously under kinetic control. The yields of the various cyclics (formed in amount often larger than that of the HP) are proportional to that of the linear HP. The latter is formed from the beginning of the reaction with a molecular weight proportional to HP yield and inversely proportional to the acid concentration. The opposite role of added water on the polymerization is discussed: an activating effect for D₃, and a desactivating one for D₄, D₅ and D₆. “Copolymerization” experiments between D₃ (or D₄) and tetramethyldisiloxane diol confirmed the effect of water and gave new informations about the occurrence - or absence - of condensation reactions in the mechanism of the growth of the polymer chains. A discussion leads to the conclusion that while the cationic polymerization of D₄ by triflic acid is propagated by activated triflic esters, that of D₃ may also involve the monomer activated by the higher hydrates of the acid and linear oligomeric silanol esters. The latter, formed continuously, may also give the D_3x cyclics by intramolecular heterocondensation.