Chitosan/polypyrrole hybrid film as multistep electrochemical sensor: sensing electrical, thermal and chemical working ambient

The reactive sensing capabilities of a mechanically stable chitosan/polypyrrole hybrid film fabricated through an in situ chemical polymerization of pyrrole are presented. The sensing abilities studied as a function of applied current, working temperature and electrolyte concentration revealed that the film can act as a multi-step electrochemical macromolecular motor, replicating basic elements of biological functions. The electrical energy consumed is a linear function of working electrical and thermal condition and a logarithmic function of electrolyte concentration. The extension of reaction (coulovoltammetric charges) is a function of and senses the working chemical ambient. The conformational changes of polymer chains (multi-step sensing motors) during reaction through the cooperative actuation make the coulovoltammetric charge a self-sensor of the working energetic conditions. This similarity of cooperative actuation of polymeric chains in biological muscles in simultaneously sensing the working condition suggests the possibility of constructing biomimetic simultaneous sensing motors using flexible chitosan/polypyrrole film with only two connecting wires.

Automated summary

This article presents the reactive sensing capabilities of a mechanically stable chitosan/polypyrrole hybrid film fabricated through an in situ chemical polymerization of pyrrole. The film can act as a multi-step electrochemical macromolecular motor and replicate basic elements of biological functions. The film's sensing abilities depend on the applied current, working temperature, and electrolyte concentration. The film's conformational changes of polymer chains during reaction make it a self-sensor of the working energetic conditions, similar to the cooperative actuation of polymeric chains in biological muscles.