Unusual Phase Transition of Poly(di(alkyl)
vinylterephthalates)
Liu, X (Liu, Xin)[ 1 ] ; Zheng, XH (Zheng, Xiao-hui)[ 1 ] ; Liu, XQ (Liu, Xiao-qing)[ 1 ] ; Zhao, RY (Zhao, Rui-ying)[ 1 ] ; Zhao, TP (Zhao, Ti-peng)[ 1 ] ; Liu, CY (Liu, Chen-yang)[ 2 ] ; Sun, PC (Sun, Ping-chuan)[ 3 ] ; Chen, EQ (Chen, Er-qiang)[ 1 ]
ACTA
POLYMERICA SINICA, 2017, 9: 1506-1516
DOI: 10.11777/j.issn1000-3304.2017.17082
WOS:000415716300011
Abstract
An unusual
phase behavior, showing the disordered phase at low temperatures and the
ordered phase at high temperatures, which is known as the "isotropic phase
reentry", has been observed in mesogen-jacketed liquid crystalline
polymers and other side-chain jacketed polymers, for example, in some
poly(di(alkyl) vinylterephthalates) (PDAVTs). In general, such a phase behavior
is considered entropy dominant. However, the mechanism underneath is not fully addressed
yet. Here, we study in detail the feature of phase transition of the PDAVT
samples with the alkyl group of butyl, hexyl and octyl (denoted as P4, P6 and
P8, respectively) by differential scanning calorimetry (DSC), X-ray diffraction
(XRD), rheology, and solid-state NMR. Undetectable in DSC experiment, the
columnar liquid crystalline (Col) phase formation is demonstrated by XRD upon
heating the PDAVT samples from isotropic state. It is also evidenced by
rheology measurement, showing that, after glass transition, the samples have
their shear storage modulus increased by two orders of magnitude at high
temperature. Upon cooling, P4 retains its Col phase probably due to the
molecular motion frozen by glass transition, while P6 and P8, which have quite low
glass transition temperature (T-g), can fully return to the isotropic state,
exhibiting the typical behavior of "isotropic phase reentry". It is
found that the Col phase formation is nucleation-limited, with the feature of
one-dimensional growth. At higher temperature, the nucleation barrier is
drastically reduced, resulting in a much faster growth rate of Col phase.
Sufficient development of the Col phase at the temperature above Tg makes the
samples solid-like. Solid-sate NMR experiment reveals that increasing the
temperature activates the alkyl tail motion first, which in fact triggers the
Col phase formation. Effects of shearing and stretching on the Col phase
formation are further examined. It is found that the external fields applied
cannot induce the isotropic-to-Col transition of PDAVT when the temperature is
close to the transition temperature, although the PDAVT chains can be oriented
to some extent. On the basis of the experimental data obtained using these
techniques, we conclude that the maximization of side-chain entropy is the
driving force for the isotropic-to-Col phase transition. Namely, only at
sufficiently high temperature can the strong side-chain motion enhance the
"side-chain jacketing" effect, making the chains more rod-like which
will pack parallelly to form the Col phase.
