This study investigates the electrochemical characterization of carbon nanotube and zincrich epoxy primers (CNT-ZRPs) on carbon steel in simulated concrete pore (SCP) solutions in the presence of chloride ions. The mechanistic performance of CNT-ZRPs was characterized by adding different zinc content. The electrochemical results indicated a dominant barrier protection effect for the coating with 60 wt% Zn while there was a mixed corrosion protection mechanism for the coating with 70 wt% Zn and a dominant cathodic protection mechanism for coatings with
Increased
adoption of engineered aluminum alloys in vehicular components
is imperative for automotive lightweighting, but such alloys are oftentimes
prone to degradation upon exposure to corrosive environments. The
design of coatings to inhibit corrosion of aluminum alloys has emerged
as a critical need but given the electropositive nature of the substrates,
only a sparse few options are available. In this article, we explore
the corrosion resistance afforded to aluminum alloy AA7075 substrates
by unfunctionalized exfoliated graphite nanocomposite coatings as
a function of the exfoliated graphite loading. Detailed mechanistic
understanding is developed through monitoring progression of the open
circuit potential and electrochemical impedance response of the substrates
over 100 days of immersion in a saline environment along with post-mortem
cross-sectional scanning electron microscopy and energy dispersive
X-ray spectroscopy analysis of sectioned interfaces. Electrochemical
studies along with nanoindentation, AC conductivity measurements,
and salt spray exposure studies allow for a direct evaluation of the
role of exfoliated graphite in inhibiting/accelerating corrosion.
Indeed, we identify two distinctive regimes: excellent long-term corrosion
resistance is obtained at low exfoliated graphite loadings within
a polyetherimide matrix as a result of a substantial enhancement in
the tortuosity of ion transport pathways for diffusion of corrosive
species; however, further inclusion of exfoliated graphite results
in formation of a percolative network that gives rise to accelerated
galvanic corrosion of the underlying substrate. Finite element modeling
shows that a broad distribution of particle sizes of graphene inclusions
is particularly favorable for enhancing tortuosity. Cross-sectional
scanning electron microscopy analysis of a 5 wt % exfoliated graphite
nanocomposite coating after salt water exposure for 100 days indicates
complete retention of coating integrity and an uncompromised interface
with the metal surface, which is in stark comparison to the bare polyetherimide
matrix, which is plagued by extensive delamination and shows significant
interfacial accumulation of corrosion products. Higher graphene loadings
beyond the percolation threshold show evidence for severe galvanic
corrosion with corrosion products distributed along the thickness
of the coating. The results provide evidence that exfoliated graphite
can offer performance that is equivalent to that of pristine and functionalized
graphene in terms of inhibiting corrosion and suggest an approach
for enhancing barrier protection through increased resistance to pore
transport enabled by the excellent dispersion of exfoliated graphite
sheets within polymeric matrices.
We explore synthetic polymeric antioxidants as powerful inhibitors of corrosion of metals. Antioxidant copolymers were designed to have polyphenol, gallol, or catechol moieties along with hydrophobic groups brought by hexyl methacrylamide units. The polymers were deposited on aluminum alloy 2024-T3 as submicrometer thick films of individual polymers or as 10 wt % additives to epoxy-based ∼100 μm thick coatings. Thin antioxidant polymer films provided significant corrosion protection of AA2024. Unlike poly(hexyl methacrylamide), which lacked polyphenol functional units, the antioxidant polymers were compatible with standard epoxy coatings and provided exceptional protection of surfaces in extreme corrosion conditions (0.6 M NaCl solution) for over 100 days. Anticorrosion performance of antioxidant-containing coatings was characterized using scanning electron microscopy, optical microscopy, and electrochemical impedance spectroscopy (EIS) and further evaluated with the equivalent electrical circuit analysis of the EIS data. Importantly, unlike small-molecule analogues, such as tannic acid, antioxidant copolymers were not leachable from epoxy coatings into water or ethanol. Taken together, these results show that antioxidant copolymers are efficient materials for protection of metals against corrosion.
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