Improvement of the existing materia

Improvement of the existing materials and developing new ones which are stronger, lighter, and more resistant to aggressive environments attracted much attention.
The conductive polymers (CPs)are still of considerable interest and importance as components of corrosion-resistant coatings [1–6].
DeBerry reported a change in the corrosion of stainless steel (SS) of the types 410 and 430 which have been coated with PANI.
The corrosion rate of SS is reduced significantly as a result of a form of anodic protection provided by the coating [1].
Such anodic protection is due to the redox states of PANI which are able to maintain the native passive film on the metal surface.
Hermas et al. [2–6] found that, the passive film of SS under CP layers has different characteristics than that formed by application of positive potential.
However, porosity and anion exchange properties of CPs could be disadvantageous particularly when it comes to pitting corrosion caused by small aggressive anions such as chlorides.
The protective properties of CPs are enhanced through blending with polymer binders.
This can be represented by the higher protective properties of PANI-based composite film containing Prussian blue and hexacyanoferrate against pitting corrosion of SS in chloride-containing acid media in comparison with bare PANI film according to Galkowski et al.[7].
PANI has attracted considerable interest in the last few decades because it is one of the best candidates for the preparation of conducting polymer-based composites.
It is stable in the normal atmosphere and significant progress has been achieved in the preparation of PANI forms able to be processed and several conductive composites of protonated PANI with insulating polymer have been reported [8–10].
The use of CPs in different matrices such as epoxy, polyvinyl alcohol (PVA) or polyacrylic (PA) blends[11–14] is a good strategy for corrosion protection with the benefit of the expected enhanced mechanical properties of such blends[15–18]. de Souza et al. used Raman spectroscopy to demonstrate electrochemical communication between iron and PANI in an acrylic blend coating [19].
PANI–PVA composite films of good quality have been obtained by Gangopadhyay et al. and showed an appreciable electrical conductivity at different temperatures[20].
Various conductive composites were prepared by chemical polymerization of aniline in the presence of several water soluble polymers and/or anionic surfactants under various polymerization conditions [21].
PVA is a well known water soluble polymer with high transparency, very good flexibility and wide commercial availability [22,23].
Based on the above mentioned, the current work is aiming to investigate the ability of the electrodeposited PANI–PVA composite to protect stainless steel against pitting corrosion.