This study prepared epoxy-clay nanocomposites (ECNs) by incorporating organophilic clays modified with either non-redox cetyltrimethylammonium bromide (CTAB) or redox-active aniline pentamer (AP), then compared their anticorrosion performance on metal substrates in saline environments. The test solution contained 2 wt% alkaline copper quaternary (ACQ) wood preservatives. Cold-rolled steel (CRS) panels coated with the ECNs were evaluated via electrochemical impedance spectroscopy (EIS) in saline media both with and without ACQ. For CRS coated with unmodified epoxy, the Nyquist plot showed impedance dropping from 255 kΩ to 121 kΩ upon adding 2 wt% ACQ-indicating that Cu2⁺ ions accelerate iron oxidation. Introducing 1 wt% CTAB-clay into the epoxy increased impedance from 121 kΩ to 271 kΩ, while 1 wt% AP-clay raised it to 702 kΩ. This improvement arises because the organophilic clay platelets create a more tortuous path for Cu2+ and O₂ diffusion, as confirmed by ICP-MS measurements of Cu2+ after EIS and oxygen permeability tests (GPA), thereby slowing iron oxidation. Moreover, ECN coatings containing AP-clay outperformed those with CTAB-clay in corrosion resistance, suggesting that AP not only enhances platelet dispersion but also promotes formation of a dense, passive metal oxide layer at the coating-metal interface, as shown by TEM, GPA, and XRD analyses. Finally, accelerated salt-spray exposure following ASTM B-117 yielded corrosion behavior consistent with the EIS results.
Keywords: ACQ; aniline oligomer; clay; corrosion; nanocomposite.