J. Heinze scite author profile

Potentiodynamic generation of polypyrrole films at an extremely low reaction rate causes the resulting material to show an additional oxidation wave that is more negative and sharper than the one normally observed. The additional peaklike oxidation wave belongs to an unknown structural entity PPy(II). The treatment of acetonitrile with basic alumina prevents its formation, whereas the addition of a low concentration of hydrochloric acid (10 -5 to 5 × 10 -5 M) to the acetonitrile electrolytic solution promotes its formation. However, higher concentrations of HCl (>10 -4 M) results in the disappearance of the characteristic peaks of both PPy(II) and the conventional PPy(I). Instead, following the acid-catalyzed trimerization of pyrrole, an ill-defined, structurally changeable, and partially conjugated PPy(III) from electrochemical side reactions may be deposited on the electrode. In a solution of high acidity, the application of a low potential to the electrolysis passivates the electrode, owing to the formation of nonconductive PPy(III) with a low degree of conjugation. A schematic mechanism for several possible pathways of pyrrole polymerization is proposed.

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Redox-active monomeric and polymeric surfactants

Anton¹,

Heinze²,

Laschewsky³

1993

Langmuir

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Influence of the Polymerization Potential on the Transport Properties of Polypyrrole Films

et al. 2009

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Polypyrrole films have been prepared by potentiostatic electrochemical polymerization at low temperatures. The cyclic voltammograms and the electronic transport properties of the films are investigated as a function of the polymerization potential. As the potential increases from 520 mV to 1.2 V, the oxidation peak moves to larger voltages, while above 1.2 V, the peak voltage drops again. The film conductivity drops monotonously as the polymerization potential is increased. However, the localization length of the current-carrying states, which characterizes the temperature dependence of the conductivity, correlates with the oxidation peak and shows a minimum for films polymerized at 1.2 V. Furthermore, we show that, with an independent doping step after polymerization, the conductivity of the films can be increased by up to 50%. A maximum conductivity of 1360 S/cm has been observed.

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J. Heinze

Electropolymerization of Pyrrole and Electrochemical Study of Polypyrrole. 2. Influence of Acidity on the Formation of Polypyrrole and the Multipathway Mechanism

Redox-active monomeric and polymeric surfactants

Influence of the Polymerization Potential on the Transport Properties of Polypyrrole Films

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