Abstract
In this work, Ce doped MgAl-LDHs layers have been developed through an in-situ synthesis method on 6082 aluminum surface. The aim was to gain mechanistic insight into the role of Ce(III) as an active corrosion inhibitor embedded in the LDHs layer. The development of the LDH structure was verified by checking the presence of the characteristic XRD peaks, the platelet morphology (evaluated by SEM-EDXS) and the functional groups (by FTIR-ATR analyses). The same techniques were employed to assess the effect of a prolonged immersion time in 0.1 NaCl on the Ce doped MgAl-LDH coatings. Electrochemical impedance spectroscopy (EIS) was employed to monitor the evolution of the electrochemical properties of the coatings during prolonged immersion in saline solutions. The findings suggest a crystallization/dissolution/precipitation mechanism which implies: (i) the formation of crystalline cerium compounds, such as Ce(OH)3, in the LDH structure during the synthesis; (ii) the dissolution upon exposure to the NaCl solution, thus leading to cerium ions release; (iii) the precipitation of amorphous Ce oxides/hydroxides at the cathodic sites when the metal starts to corrode; (iv), the consequent mitigation of the electrochemical activity of the metal and, thus, the reduction of the extent of corrosion.
Highlights
Chromate conversion coatings (CCC) have been widely used as anticorrosive treatments for zinc, steel, and aluminum alloys until 2006 [1,2,3] thanks to the undeniable active corrosion protection (ACP) provided by Cr(VI) species
Numerous studies have been aimed towards the substitution of Cr(VI) based surface conversion treatments for corrosion protection purposes
In addition to the well-established surface conversion treatments, recently, a new class of talcite-based coatings has been deeply investigated as a promising surface finishing for corrosion protection purposes
Summary
Chromate conversion coatings (CCC) have been widely used as anticorrosive treatments for zinc, steel, and aluminum alloys until 2006 [1,2,3] thanks to the undeniable active corrosion protection (ACP) provided by Cr(VI) species. In addition to the well-established surface conversion treatments, recently, a new class of talcite-based coatings (namely layered double hydroxides, LDHs) has been deeply investigated as a promising surface finishing for corrosion protection purposes. According to into the recent reGenerally, anions having high charge are preferentially intercalated the LDH views on this topic [40,41], several based coatings were developed by the in-situ complex [37,38,39]. LDHs layers prior and thecontaining exposure to a saline containing were priorwere and evaluated after the exposure to after a saline environment to invesenvironment thethe role of the cerium on occurring the corrosion processes occurring tigate the roleto of investigate the cerium on corrosion processes on the metal surface.
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