PIB is an unusual polymer, having d

PIB is an unusual polymer, having distinctive characteristics
such as (i) very low permeability [1] due to slow diffusion of dissolved
gases; (ii) a propensity for strain-induced crystallization
[2,3] despite slow thermal crystallization; (iii) high mechanical
damping and energy dissipation [4,5]; and (iv) anomalous
segmental relaxation dynamics [6,7] that includes a spectacular
breakdown of time-temperature superpositioning [8]. These
properties have led to many applications [9]. PIB is also resistant to
crosslinking, either free radical initiated or by sulfur vulcanization,
and consequently commercial PIB (“butyl rubber”) is usually a
copolymer with isoprene to provide reactive sites. However, only
2e5 mol% isoprene can be incorporated; thus, butyl rubber cures
very slowly and only to a limited degree. Various isobutylene block
copolymers [10e16] have been synthesized, and thermoplastic PIB
elastomers are particularly intriguing for their commercial potential
[17e21].
Recently the controlled/living emulsion copolymerization of
isobutylene with 2,6-dimethyl-2,4,6-octatriene (alloocimene or
“allo”) was reported, yielding block copolymers with allo-rich sequences
coupled to polyisobutylene (PIB) [22,23]. A detailed
description of the triblock synthesis will be published [24]. The
diblock polymers exhibit thermoplastic elastomer properties, with
allo-rich domains serving as physical crosslinks. Preliminary characterization
of the triblock PIB-allo copolymers indicated significant
tensile strength (~12 MPa) and elongation (600%) [22]. The
conjugated diene side chains of the allo units also provide the
possibility for chemical modification. Due to the high allo content,
these thermoplastic elastomers cure very efficiently and much
faster than butyl rubber. In this work we characterize the mechanical
properties and their relation to structure in a poly(allo)-b-
PIB-b-poly(allo) triblock copolymer.