Effect of Crystallographic Orientation on the Corrosion of Magnesium: Comparison of Film Forming and Bare Crystal Facets using Electrochemical Impedance and Raman Spectroscopy

Bland, Leslie G.; Gusieva, Kateryna; Scully, John R.

doi:10.1016/j.electacta.2016.12.107

Cited by 120 publications

(45 citation statements)

References 79 publications

(166 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…This response is commonly observed with Mg and Mg alloys under these types of exposure conditions. 39 4.0x10 -6 6.0x10 -6 8.0x10 values (R p ) were estimated using a method derived from the KramersKronig transforms. 42,43 According to this method, the polarization resistance can be estimated from the imaginary component of the impedance integrated over the measured frequency domain: integral of each fit over its frequency range was computed (Fig.…”

Section: Resultsmentioning

confidence: 99%

Corrosion Inhibition Study of Aqueous Vanadate on Mg Alloy AZ31

Feng

Hurley

et al. 2018

J. Electrochem. Soc.

View full text Add to dashboard Cite

Corrosion inhibition of AZ31 Mg alloy with aqueous vanadate was studied and has been attributed to the pH dependence of vanadate speciation. Immersion in tetrahedral coordinated vanadate species, present in neutral and alkaline solution, was shown to decrease corrosion current density and increase the breakdown potential, both of which were enhanced with longer immersion times. Exposure to octahedral coordinated vanadate, predominant in acidic solution, only slightly decreased corrosion current density. An acidic solution was adjusted to alkaline conditions and samples were immersed in the adjusted alkaline solution. Inhibition of these samples was weaker than that of samples immersed in initially alkaline solutions. Anodic inhibition was observed on samples treated in solutions containing tetrahedral species. SEM images showed that vanadate formed a film across secondary particles and the Mg matrix, and provided qualitative evidence that inhibition efficiency increased as the pH increased. XPS results indicated that film formation was associated with the reductive adsorption of vanadium oxoions. Exposure at pH 5.0 produced a film predominated by V 4+ . Exposure at pH values of 7.7 and higher, however, produced a film containing predominantly V 3+ . Mg alloys have attracted great attention due to their high strength/weight ratio, good thermal conductivity and other physical properties.1-3 They have been widely used in the automotive industry, as aerospace components, and in the field of electronics.4-9 However, Mg alloys have high chemical activities, and are susceptible to corrosion, especially galvanic corrosion arising from interactions with more noble materials such as steel.10 Their active corrosion behavior is a barrier to wider applications. Therefore, protection under various application conditions is a critical issue strongly worthy of investigation. 11,12Extensive research has been conducted with the goal of inhibiting corrosion and improving the corrosion resistance of Mg alloys. Many corrosion mitigation methods have been reported, including alloying, surface modification, coatings, and inhibitors.13-15 Birbilis et al. studied the effect of numerous alloying elements on the corrosion kinetics of Mg, graphically presenting the effect of anodic and cathodic kinetics on over 30 alloying elements. 16,17 These detailed studies of alloying elements provided beneficial information for the fabrication, modification and development of corrosion-resistant Mg alloys. Surface modification of Mg alloys includes anodizing, 18 hot diffusion, 19 laser treatment 20 and other treatments that affect the surface, but do not change the original mechanical properties of the alloy.15 Surface modification can increase polarization resistance and reduce the localized galvanic interactions that arise from the heterogeneous structure found in these alloys. 15,[18][19][20] Conversion coatings are another effective method to improve the corrosion resistance of Mg alloys.21 These coatings can provide excellent protection of the s...

show abstract

Section: Resultsmentioning

confidence: 99%

Corrosion Inhibition Study of Aqueous Vanadate on Mg Alloy AZ31

Feng

Hurley

et al. 2018

J. Electrochem. Soc.

View full text Add to dashboard Cite

show abstract

“…The quality of the fit is attributed to the fact that there were slow changes in the corrosion rate in the present work as is evident from Figures . The fit was not as good as those by Gomes et al and those of Scully and co‐workers; however, those works used solutions that were much less corrosive, so the corrosion behavior was much more stable, and there was much less change in corrosion behavior during the measurement of EIS spectra. The corrosion rates evaluated from the EIS data, P i,EIS,1 and P i,EIS,2 , were consistently smaller than the corrosion rates evaluated from the evolved hydrogen P H .…”

Section: Resultsmentioning

confidence: 62%

“…Comparison of the corrosion rates, P H , P i,EIS,Rp1 , P i,EIS,Rp2 , and P i,EIS,CT of the WE43B specimen designated as WE29 immersed at the open‐circuit potential in 0.6 M NaCl solution saturated with Mg(OH) 2 for 7 days, where P H is instantaneous corrosion rate evaluated from the volume of evolved hydrogen, P i,EIS,Rp1 is the corrosion rate calculated from the resistance at the lowest frequency, and P i,EIS,Rp2 is the corrosion rate evaluated from the polarization resistance calculated using Equation , and P i,EIS,CT is the corrosion rates calculated from the charge transfer resistance, R 1 …”

Section: Resultsmentioning

confidence: 99%

“…Figure shows the MgO film thickness on specimens WE29 and ZE21 over the test period, which was calculated using

C = \frac{ε ε_{0} A}{l_{ox}},

where C is C 1 or C PE , (10 −6 F/cm 2 ), ε is the dielectric constant for MgO (9.8 dimensionless), ε 0 is the permittivity of vacuum (8.84 × 10 −14 F/cm), A is the specimen surface area (cm 2 ), and l ox is the thickness of the MgO layer (nm). Figure shows that the MgO film thickness on WE29 continued to grow from an initial value of 3 nm over the test period.…”

Section: Resultsmentioning

confidence: 99%

“…Scully and colleagues and Liu et al proposed that EIS data for Mg corrosion, which includes an inductive loop, can be fitted to the equivalent circuit given in Figure , where R s is the solution resistance, C 1 represents the capacitance of the surface oxide (MgO), C 2 represents the double‐layer capacitance, R 1 represents the charge transfer resistance, R 2 is the oxide resistance, R 3 is the resistance of a fresh anode with adsorbed species, and the inductor L represents a reaction involving adsorbed intermediates. They maintained that (a) the equivalent circuit is physically realistic and contains the minimum number of circuit elements to explain the EIS data, and (b) the corrosion current density, i corr , can be evaluated from the Stern–Geary equation:

i_{corr} = \frac{β_{a} β_{c}}{2.30 R_{p} (β_{a} + β_{c})} = \frac{B}{R_{p}},

where

β_{a} normal and normal normal β_{c}

are the anodic and cathodic Tafel constants (

β_{c}

has a negative value) and R P is the polarization resistance, evaluated as the difference between R s and the low‐frequency asymptote of the impedance as the frequency tends to zero. The equivalent circuit in Figure indicates that R P can be evaluated from:

\frac{1}{R_{P}} = \frac{1}{R_{1} + R_{2}} + \frac{1}{R_{3}} .

…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Corrosion of Mg alloys EV31A, WE43B, and ZE41A in chloride‐ and sulfate‐containing solutions saturated with magnesium hydroxide

Soltan

Dargusch

Shi

et al. 2019

Materials & Corrosion

View full text Add to dashboard Cite

This study studied corrosion in 0.1 M Na 2 SO 4 , 0.1 M NaCl, and 0.6 M NaCl, all saturated with Mg(OH) 2 , using weight loss, hydrogen evolution, and electrochemical measurements. Corrosion was similar in all cases. Nevertheless, the corrosion rates were alloy-dependent, were somewhat lower in 0.1 M Na 2 SO 4 than in 0.1 M NaCl, and increased with NaCl concentration. The corrosion damage morphology was similar for all solutions; the extent correlated with the corrosion rate. The corrosion rates evaluated by the electrochemical methods were lower than those evaluated from hydrogen evolution, consistent with the Mg corrosion mechanism involving the unipositive Mg + ion. K E Y W O R D SEIS, hydrogen evolution, magnesium, polarization, SEM

show abstract

Controlled Stepwise Wet Etching of Polycrystalline Mo Nanowires

Saidov,

Erofeev,

Aabdin

et al. 2023

Adv Funct Materials

View full text Add to dashboard Cite

With the persistent downscaling of integrated circuits, molybdenum (Mo) is currently considered a potential replacement for copper (Cu) as a material for metal interconnects. However, fabricating metal nanostructures with critical dimensions of the order of 10 nm and below is challenging. This is because the very high density of grain boundaries (GBs) results in highly non‐uniform surface profiles during direct wet etching. Moreover, wet etching of Mo with conventional aqueous solutions is problematic, as products of Mo oxidation have different solubility in water, which leads to increased surface roughness. Here, a process is shown for achieving a stable and uniform soluble surface layer of Mo oxide by wet oxidation with H2O2 dissolved in IPA at −20 °C. The oxide layer is then selectively dissolved, and by repeating the oxidation and dissolution multiple times, a uniform etch profile is demonstrated with a fine control over the metal recess. Ultimately, this presents a method of precise and uniform wet etching for Mo and other metals needed to fabricate complex nanostructures that are critical in developing next‐generation electronic devices.

show abstract

Effect of Crystallographic Orientation on the Corrosion of Magnesium: Comparison of Film Forming and Bare Crystal Facets using Electrochemical Impedance and Raman Spectroscopy

Cited by 120 publications

References 79 publications

Corrosion Inhibition Study of Aqueous Vanadate on Mg Alloy AZ31

Corrosion Inhibition Study of Aqueous Vanadate on Mg Alloy AZ31

Corrosion of Mg alloys EV31A, WE43B, and ZE41A in chloride‐ and sulfate‐containing solutions saturated with magnesium hydroxide

Controlled Stepwise Wet Etching of Polycrystalline Mo Nanowires

Contact Info

Product

Resources

About