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Electrically active polymers electrochemical cells

The Faradaic activity of thin films of pol3nneric phthalocyanines 31 (M = Cu(II)) on titanium foils in electrochemical cells has been investigated [94]. Electrodes with the polymer film dipped into an aqueous solution of K3Fe(CN)6/K4Fe(CN)6 exhibit a high Faradaic activity and reversibility comparable to a bare platinum electrode. The electrically conductive polymer allows an efficient electron transfer to redox couples in solution. Thin films of... [Pg.244]

The anode layer of polymer electrolyte membrane fuel cells typically includes a catalyst and a binder, often a dispersion of poly(tetraflu-oroethylene) or other hydrophobic polymers, and may also include a filler, e.g., acetylene black carbon. Anode layers may also contain a mixture of a catalyst, ionomer and binder. The presence of a ionomer in the catalyst layer effectively increases the electrochemically active surface area of the catalyst, which requires a ionically conductive pathway to the cathode catalyst to generate electric current (16). [Pg.145]

Furthermore, porous CPs (e.g., polypyrrole, polyanUine) films have been used as host matrices for polyelectrolyte capsules developed from composite material, which can combine electric conductivity of the polymer with controlled permeability of polyelectrolyte shell to form controllable micro- and nanocontainers. A recent example was reported by D.G. Schchukin and his co-workers [21]. They introduced a novel application of polyelectrolyte microcapsules as microcontainers with a electrochemically reversible flux of redox-active materials into and out of the capsule volume. Incorporation of the capsules inside a polypyrrole (PPy) film resulted in a new composite electrode. This electrode combined the electrocatalytic and conducting properties of the PPy with the storage and release properties of the capsules, and if loaded with electrochemical fuels, this film possessed electrochemically controlled switching between open and closed states of the capsule shell. This approach could also be of practical interest for chemically rechargeable batteries or fuel cells operating on an absolutely new concept. However, in this case, PPy was just utilized as support for the polyelectrolyte microcapsules. [Pg.470]

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See also in sourсe #XX -- [ Pg.388 , Pg.389 ]



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Active polymers

Cell, electric

Electric activation

Electric polymers

Electrical activation

Electrical activity

Electrically active polymers

Electricity electrochemical

Electrochemical activity

Electrochemical cell

Electrochemically activated

Electrochemically active

Electrochemically active polymers

Polymer activities

Polymer cells

Polymers activator

Polymers electrical

Polymers electrochemical activation

Polymers, activation

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