23.2.4 PA
PA, previously known as polyene, was synthesized by polymerization of acetylene and was
reported by Natta et al. through a noble lecture in 1963 [9]. Shirakawa et al., in their noble
lecture, mentioned that the discovery of the PA film was a fortuitous error and possess
intrinsic electrical properties, which didn’t vary between its powder and film form [10].
Later, due to carbocation of PA, the charge carrier was termed a conducting polymer.
Synthesis of PA is mainly being carried out by three processes: a) catalytic polymerization,
b) non-catalytic polymerization, and c) precursor assisted synthesis. Ziegler–Natta catalysts
offer a good choice for catalytic polymerization owing to good solubility in organic
solvents. For a high molecular weight PA, a luttinger catalyst is used, which utilizes acet
onitrile and other hydrophilic solvents. Further, non-catalytic polymerization of the PA
includes electrochemical polymerization, where aniline monomers are deposited on the
metallic electrode to get a uniform PA film. Ring-opening polymerization is another
method of synthesis, which doesn’t require any catalyst and electro-machine setup.
23.2.5 PEDOT
PEDOT is a popular member of this group and the very first material used as an electrode on
the human brain [11]. The PEDOT properties depend on the chemical structure, fabrication
condition, incorporation of surfactants or doping, polymer composition, post-treatment, and
polymerization. PEDOT is both n- and p-dopable and also displays electronic, electrical,
and magnetic properties akin to metals and semiconductors. To develop PEDOT with me
chanical stability, conductivity, and degradation under a change in temperature, pressure, or
time strategies of both fundamental and practical are ensured according to the application.
PEDOT itself and its derivatives are highly transparent in the visible range therefore suitable
as flexible transparent electrodes.
23.2.6 PVDF
PVDF is a widely explored piezoelectric, thermo-mechanically stable, organic polymer for
bioelectronic applications because of its flexible electroactive and processing properties.
It exists in three dominant polymorphic forms, α, β, and γ. Among the three phases, the
β-phase is for the most part electroactive because of the all-trans (TTTT) configuration and
high dipole moment induced from CH2-CF2 [12]. The copolymerization of vinyl di
fluoride with trifluoroethylene (PVDF-TrFE) also enhances the piezoelectric response
inducing chain alignment and high crystallinity [13].
23.3 Flexible Bioelectronics Synthesis, Fabrication, and Structural Design
PTh: Samanta et al. doped PTh with poly(ethylene glycol) (PEG)2000 and sodium p-toluene
with synthesized PTh-g-poly (dimethylamino ethylmethacrylate) using atom transfer ra
dical polymerization (ATRP) technique. The graft copolymer using methylcellulose gel was
investigated the result showed photoluminescence property with change in temperature
and pH. The graft copolymer showed similarity to AND logic gate functions, whereas the
change in polarity in hydrogel at microenvironment was altered by the temperature and
pH, which acted as an input, therefore resulting in fluorescent output [14]. The conductive
Conducting Polymer-Based Biocomposites
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