The preparation of poly(dimethylsiloxane)s
having part of the siloxane units substituted
with a model organic thioether was investigated. The sulfur group
was generated by the ene−thiol
addition to the vinyl function bound to silicon. Two synthetic
routes to this copolymer were compared (i)
one-step kinetically controlled polymerization of
organosulfur-substituted hexamethylcyclotrisiloxane and
(ii) two-step synthesis including kinetically controlled polymerization
of 1,3,3,5,5-pentamethyl-1-vinylcyclotrisiloxane followed by the thiol addition to the vinyl group
in the polymer. A cryptand−lithium
silanolate complex generated from
[(trimethylsilyl)methyl]lithium was selected as the
initiator in this
polymerization, while tert-butyl mercaptan was used as the
hydrosulfidation reagent. It was shown that
synthesis routes lead to a high yield of copolymers having a fairly
regular chain structure. The
arrangement of siloxane units in the polymer chain was controlled by
the propagation step. Polymerization
of the vinyl-substituted monomer exhibited a significant degree of
regioselectivity as one of the three
possible modes of the monomer ring opening contributed over 70% to the
propagation. Addition of t-BuSH
to the vinyl group in the polymer proceeded without rearrangement of
the polymer chain and could be
performed without any side reaction of the vinyl group. Model
copolymers of regular alternating structure
were synthesized by the heterofunctional polycondensation of
[2-(tert-butylthio)ethyl]methyldichlorosilane
with a series of diols,
HO(Me2SiO)
n
H, n
= 1−4. They were used for comparison with the
copolymers
obtained by ring-opening polymerization.
sBuLi and tBuLi have been combined with a new family of ligands, i.e. lithium silanolates, and used as initiators for the ligated anionic polymerization (LAP) of methyl methacrylate (MMA) in toluene at 0 °C. Compared to other known µ-ligands, the accordingly formed Bu(Me 2)SiOLi are more efficient stabilizers for the active centers. Under appropriate reaction conditions, a fast polymerization proceeds quantitatively without self-termination at 0 °C and leads to high molecular weight polymer of narrow molecular weight distribution (M h w/M h n < 1.2) and high isotacticity (90% isotactic triads).
The mixed associated species {xsBuLi,
(y − x)sBuMe2SiOLi} formed
by reaction of sec-Butyllithium (sBuLi) with octamethylcyclotetrasiloxane
(Me2SiO)4 in toluene have been used to
initiate
the anionic polymerization of methyl methacrylate (MMA) in that solvent
at 0 °C. The active species
generated by this new type of initiator have been characterized by
7Li NMR at 0 °C. The 7Li NMR
spectra
of sBuLi and sBuMe2SiOLi mixtures in toluene show that
only one single type of {sBuLi,
5sBuMe2SiOLi}
mixed species prevails at [sBuMe2SiOLi]/[sBuLi]
molar ratios higher than ca. 21, as result of a large
excess of {6sBuMe2SiOLi} species. The
7Li NMR has also concluded to the formation of
{PMMALi,
5sBuMe2SiOLi} species upon the addition of MMA to
that initiator solution, supporting the theory that
only one type of ionic species is active during the MMA conversion.
These active centers are stable for
at least 1 h at 0 °C as confirmed by 7Li
NMR.
It has been well-known for a very long time that, for
anionic homo-polymerization or
sequential copolymerization to occur, it is mandatory that the relative
nucleophilic reactivity of the
initiating species be equal to or larger than the one of the
(co)monomer. However, the results described
in this paper demonstrate that such a classic rule can be circumvented
in some cases. Indeed, it is reported
for the first time that potassium trimethylsilanolate, and “living”
potassium poly(ethylene oxide), both of
which are unable to initiate styrene or methyl methacrylate (MMA)
polymerization, can be converted
from oxyanionic active ends to silyl anionic ones by reacting with
cyclic disila derivatives, so allowing
the homopolymerization and sequential (co)polymerization of
styrene or MMA to proceed in a controlled
manner.
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