This paper discusses a new family of ferroelectric polymorphic fluoroterpolymers comprosed
of vinylidene difluoride (VDF), trifluoroethylene (TrFE), and a chloro-containing third monomer, such as
chlorodifluoroethylene (CDFE), and chlorotrifluoroethylene (CTFE), which feature relatively narrow
molecular weight and composition distributions. The terpolymers were prepared by a bulk reaction process
with a low temperature free radical initiator, i.e., the oxidation adducts of trialkylborane and oxygen.
The slightly bulky chlorine atom serves as a kink in the polymer chain, which spontaneously alters the
chain conformation and crystalline structure. Compared to the corresponding VDF/TrFE copolymer (>20
mol % of TrFE), the slowly increasing chlorine content (<8 mol % of termonomer) gradually changes the
all-trans (t
m
>4) chain conformation (β-phase) to tttg+tttg- conformation (γ-phase) without significant
reduction of overall crystallinity. The Curie (ferroelectric−paraelectric) phase transition temperature
between the mixed ferroelectric β- and γ-phases and paraelectric α-phase (tg+tg- conformation) also
gradually reduced to near ambient temperature with very small activation energy. Consequently, the
terpolymers show high dielectric constant (>70), slim polarization hysteresis, and large electrostrictive
response (>4%) at ambient temperature and exhibit common ferroelectric relaxor behaviors with a broad
dielectric peak that shifted toward higher temperatures as the frequency increased.
Terpolymers of vinylidene fluoride (VDF), trifluoroethylene (TrFE), and chlorotrifluoroethylene (CTFE) were synthesized as potential materials for electromechanical transduction.
These terpolymers had relatively high molecular weights (∼30 kg/mol) and CTFE levels in
the range of 5−10 mol %. The presence of the bulky CTFE units disrupts the sequence length
of the crystal, which lowers both the melting and Curie transitions; however, the degree of
crystallinity remains high. The formation of smaller, more mobile polar domains gives rise
to good electromechanical response. At low electric fields (7 MV/m), longitudinal strains as
high as 0.5% are attained. This is significantly higher than the strains achieved with the
same terpolymer obtained by bulk polymerization. The present materials exhibit a low
mechanical modulus (ca. 0.2 GPa) relative to other VDF−TrFE copolymers. This might limit
their use, depending on the application.
This paper discusses a new ferroelectric polymer with large electrostrictive response (-4%) at ambient temperature, which is based on a processable semicrystalline terpolymer comprising vinylidene difluoride (VDF), trifluoroethylene (TrFE), and chlorotrifluoroethylene (CTFE). This VDFITrFEICTFE terpolymer was prepared by a combination of bulk polymerization process and a borane/oxygen initiator at ambient temperature. The incorporated bulky CTFE units in the terpolymer seem to reduce the crystalline domain size and move the ferroelectric-paraelectric (F-P) phase transition to near ambient temperature with a very small energy barrier. Some terpolymers exhibited common ferroelectric relaxor behaviors with a broad dielectric peak that shifted toward higher temperatures as the frequency increased, and a slim polarization hysteresis loop at near the dielectric peak (around ambient temperature) that gradually evolved into a normal ferroelectric polarization hysteresis loop with reduced temperature.
Immobilization methods have emerged as feasible solutions for increasing the re-usability of biocatalysts, and for simplifying their separation from the desired products. Immobilized biocatalysts can directly be applied to a...
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