Film Breakdown and Nano-Porous Mg(OH) 2 Formation from Corrosion of Magnesium Alloys in Salt Solutions

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A sequential isotopic tracer study of corrosion film growth for Mg-3Al-1Zn-0.25Mn (AZ31B) and Mg-1.2Zn-0.25Zr-<0.5Nd (ZE10A) was conducted by 4 h immersion in H 2 18 O or D 2 16 O, followed by a 20 h immersion in a 0.01 wt% NaCl H 2 18 O or D 2 16 O solution. Sputter depth profiles were obtained for 16 O, 18 O, H, and D using secondary ion mass spectrometry (SIMS). Compared to the previous tracer study for these alloys in salt-free water, the addition of 0.01 wt% NaCl resulted in a transition from oxygen inward-dominated film growth to a component of mixed inward/outward film growth for both alloys. The hydrogen tracer behavior remained inward growing for AZ31B, and short-circuit, inward growing for ZE10A, in both pure water and in 0.01 wt% NaCl solution, with extensive penetration of D beyond the film and into the underlying alloy also observed for ZE10A. Analysis of the films by X-ray photoelectron spectroscopy (XPS) and cross-section scanning transmission electron microscopy (STEM) indicated intermixed Mg(OH) 2 and MgO, with the relative fraction of Mg(OH) 2 peaking near the center of the film. These findings suggest a decoupled film growth mechanism, with initial formation of oxide followed by NaCl-accelerated conversion to hydroxide, likely by both solid-state and dissolution-precipitation processes. Low density Mg alloys are of great interest for the production of lightweight vehicle parts to achieve increased fuel efficiencies and better performance.1-6 Key challenges to achieve widespread adoption in automotive vehicle applications include the cost of primary Mg metal, the formability of wrought Mg alloys (to expand application beyond current Mg cast parts), and the rapid corrosion of Mg in many aqueous and humid environments.6 From a corrosion perspective, the high reactivity of Mg, which leads to micro-and/or macro-galvanic corrosion coupling, and the inability of Mg alloys to sufficiently establish and/or maintain a protective surface film are major challenges in many environments. [7][8][9][10][11][12][13][14] Of particular detriment is the acceleration of Mg corrosion in salt-containing environments, which has been linked to increased local micro-galvanic coupling at second phases/metallic impurity sites and enhanced Mg dissolution, as well as disruption of the Mg(OH) 2 /MgO based surface film. The successful application of isotopic tracer studies employing secondary ion mass spectrometry (SIMS) to gain insights into the film growth mechanism of Mg alloys in room-temperature water and 85• C humid air was recently demonstrated. 45,46 Isotopic tracer studies have been widely used in oxidation studies of Al-, Fe-, Ni-, and Zr-base alloys, as well as SiC, with significant new insights gained regarding the growth mechanism of the oxide films. 45,[47][48][49][50][51][52][53][54][55][56][57][58][59][60][61][62][63][64][65] However, application of this experimental approach to Mg is particularly challenging due to the formation of both MgO and Mg(OH) 2 products in the film, necessitating the use of both ...

Section: Resultsmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

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Tracer Film Growth Study of the Corrosion of Magnesium Alloys AZ31B and ZE10A in 0.01% NaCl Solution

Brady¹,

Fayek²,

Leonard³

et al. 2017

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“…The theoretically calculated surface energies of Mg (0001), and (11)(12)(13)(14)(15)(16)(17)(18)(19)(20) 33 A higher surface energy can result in an increased dissolution rate. The theoretical dissolution rates of Mg crystallographic planes (10-10) and (11)(12)(13)(14)(15)(16)(17)(18)(19)(20) are predicted to be about 18-20 times higher than that of the basal plane (0001). 34 A corrosion study on a hcp Zn single crystal showed that the corrosion resistance of the (0001) basal plane is about 1.4 times that of the (1120) and (1010) planes in 1 M (NH 4 ) 2 SO 4 .…”

Section: Discussionmentioning

confidence: 99%

Corrosion Behavior of Pure Magnesium with Low Iron Content in 3.5 wt% NaCl Solution

Yang

Zhou

Curioni

et al. 2015

The microstructure and corrosion behavior of pure magnesium, with 25 ppm Fe but a high corrosion rate, have been studied in this work. It was found that Fe-rich particles, containing also Si, distribute non-uniformly in the Mg matrix and they are spaced at a distance of 100-1000 μm. Before the initiation of localized corrosion, Fe-rich particles play a key role in determining the overall corrosion behavior by supporting hydrogen evolution. During corrosion propagation, Fe-rich particles could be oxidized once they were detached from the Mg matrix and, consequently, lose their cathodic activation. Once the corrosion has taken place over majority of the surface, the effects of crystallographic orientation of the underlying metal dominate the last stage of corrosion, which propagates parallel to the (0001) Magnesium alloys are of great value for industrial applications due to their low density and high strength-to-weight ratio. However, a major deficiency is their comparatively poor corrosion resistance when exposed to aqueous and humid environments.1,2 Consequently, there is a demand to develop magnesium alloys with improved corrosion resistance. 2,3The equilibrium potential for magnesium oxidation is well below the equilibrium potential for hydrogen evolution over the entire pH range of practical interest. As a consequence, the cathodic reaction of hydrogen evolution largely dominates over oxygen reduction during corrosion in an aqueous environment. For this reason, the presence of elements with low overpotentials (or high exchange current density) for hydrogen evolution is likely to produce detrimental effects on the corrosion resistance due to increase in the hydrogen evolution rate. Hanawalt et al. 4 found that four elements (Fe, Ni, Cu, and Co) had a very profound effect on accelerating the corrosion rate of Mg in chloride-containing aqueous environments even at concentrations below 0.2 wt%. Subsequent studies have confirmed that the most critical factor affecting the corrosion behavior of Mg is the presence of impurities.3

“…19,[22][23][24][25][26] Cathodically active sites have been examined through the use of scanning vibrating electrode technique (SVET) on 99.9% 25 and 99.99% 23 pure Mg, Mg-Nd binary alloys 24 and AZ31. 22,27 To date, mechanisms have been proposed, which explain this behavior, including: (i) transition metal enrichment from impurities, 28,29 (ii) particle enrichment to the oxide layer 26,30,31 and (iii) Al redeposition. 30 Evidence of cathodic activation has been noted to also be influenced by cathodic sites upon the Mg sample surface, namely intermetallic particles (IMPs) and impurities.…”

mentioning

confidence: 99%

Exploring the Effects of Intermetallic Particle Size and Spacing on the Corrosion of Mg-Al Alloys Using Model Electrodes

Bland

Birbilis

Scully

2016

The effect of the area fraction, size and distribution of model cathodic, intermetallic particles (IMPs) in an anodic Mg matrix on corrosion was investigated. Model Mg-Al electrodes were developed to study IMP effects in isolation from other metallurgical effects, with particles simulated by Al electrodes embedded in a Mg matrix. Arrays of model Mg-Al electrodes were constructed using high purity Al as a surrogate for Al-rich IMPs and flush mounted in commercial purity Mg. The area fraction, size and spacing of these electrodes each altered the corrosion rate and cathodic reaction kinetics assessed after a 24 and 48 hour immersion period at the open circuit potential. Corrosion rate increased with increasing area fraction of Al electrodes but decreased with increasing electrode spacing given a fixed area fraction. The affected zone around electrodes and at the Al/Mg interface was explored to ascertain its impact on the resultant global corrosion rate and kinetics. The effect of local pH at the Al electrode on the prospects for Al corrosion and chemical redeposition were also explored. Magnesium (Mg) alloys continue to be of growing interest due to their good balance of specific properties (i.e. properties relative to weight).1-3 However, due to the inherently negative electrochemical potential of Mg and its alloys, 4,5 Mg-alloys are highly reactive compared to other engineering metals. Mg-alloys are susceptible to several forms of localized corrosion, whilst also highly prone to macro-as well as micro-galvanic corrosion. Due to the low solid solubility of most alloying elements in Mg 6 and particularly low solubility limits for most transition elements; secondary phases readily form during most types of material processing, including casting 7,8 and welding, 9-15 which can adversely alter the corrosion performance.There are many secondary phases, or intermetallic particles (IMPs), which are particularly common in Mg alloys. Each IMP 16 has its own unique dissolution or reduction kinetics, dependent on its composition, size and dispersion within the material. For example, in the Mg-Al alloys which contain Mn (such as AZ31, AZ91 and AM50), Al-Mn IMPs that are rich in Al such as Al 4 Mn, Al 6 Mn, display relatively low rates of cathodic kinetics in comparison to other IMPs that are rich in Mn such as Al 8 Mn 5 ; the latter displaying relatively rapid cathodic kinetics. 1,7,17 Similarly, the so called Al-Mn-Fe IMPs, such as Al 8 (Mn,Fe) 5 function as highly potent cathodic sites in Mg, although the Mn has been shown to prevent some of the detrimental galvanic effects of Fe impurities by incorporating the Fe into the Al-Mn IMPs. 1,6,16 Furthermore, Mg-Zn IMPs have approximately the same open circuit potential (OCP) as many Mg alloys. However, the cathodic kinetics of this IMP are more rapid than Mg, 16 attributed to the presence of Zn. Mg-Zn IMPs are cathodic to the α-Mg and, therefore, tend to cause localized corrosion through micro-galvanic coupling which is often manifest at the Mg matrix/IMP interface. Some ...