Electrochemical behaviour of a Mg-rich primer in the protection of Al alloys

Battocchi, Dante; Simões, A.M.; Tallman, Dennis E.; Bierwagen, Gordon P.

doi:10.1016/j.corsci.2005.04.008

Cited by 136 publications

(124 citation statements)

References 14 publications

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“…10 While the exact configurations such as electrolyte thickness, concentration and polymer resistances differ from this work, several configurations were chosen for comparison and the results are summarized in Table I where the results show good correlation. It is to be noted that while FEA predicts the galvanic current for fixed conditions, such as fixed electrolyte chemistry and thickness, SVET can be utilized to study the current density distributions as a function of actual position and time dependent electrolyte solution chemistry and pH and also surface modifications such as formation of Mg(OH) 2 and effects of inhibitor leaching from the pretreatment. The FEA model uses fixed Elogi boundary conditions and predicts the quasi-steady state galvanic current and galvanic couple potential distribution.…”

Section: Discussionmentioning

confidence: 99%

“…Anionic species leaching from the pretreatment might also bring down the anodic activity at defect by acting as cathodic inhibitor. The protection of the defect by Mg(OH) 2 and anionic species leaching in both lab accelerated life testing (LALT) and field exposures for pretreated systems has been previously reported. 4,7,8 Further investigation of the chemical protection mechanism and the conditions required for chemical protection will be reported in future work.…”

Section: 29mentioning

confidence: 99%

“…1 Over the past few years, a commercial organic coating system containing a Mg-rich primer (MgRP) has been developed for the active corrosion protection of aerospace aluminum alloys. [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17] The commercial MgRP coating system consists of a surface pretreatment, an epoxy resin with metallic Mg pigment and, where applicable, a polyurethane topcoat. The active corrosion protection of any Al alloy is provided by galvanic coupling of more active Mg pigment in the primer which is active compared to the more noble AA2024-T351 substrate.…”

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confidence: 99%

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Performance of a Magnesium-Rich Primer on Pretreated AA2024-T351 in Full Immersion: a Galvanic Throwing Power Investigation Using a Scanning Vibrating Electrode Technique

Kannan

Glover

McMurray

et al. 2018

J. Electrochem. Soc.

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The scanning vibrating electrode technique (SVET) was employed to examine the effect of 'galvanic throwing power' and the distance over which a Mg-rich primer (MgRP) provided sacrificial anode-based cathodic protection to AA2024-T351. Three systems were investigated in full immersion conditions where the same MgRP was used with three different pretreatments: Non-film forming (NFF), trivalent chromium pretreatment (TCP) and anodization with a chromate seal (ACS). Experiments were conducted with two coating/defect area ratios and three parameters were monitored: 1) the maximum peak height of local anodes, inferring the location and intensity of pits, 2) the current density profile at the coating/defect interface (CDI) region and 3) total integrated anodic and cathodic current density values of defined areas in the defect region moving progressively away from the CDI. The NFF-based system was shown to provide the superior galvanic throwing power and a quasi-steady-state galvanic current distribution was detected in the defect region adjacent to the CDI indicating enhanced cathodic activity in response to the MgRP. High resistance between the MgRP and the substrate, due to the thickness of the pretreatment layer, appeared to mediate galvanic interactions in the case of TCP and ACS-based systems.

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Section: Discussionmentioning

confidence: 99%

Section: 29mentioning

confidence: 99%

mentioning

confidence: 99%

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Performance of a Magnesium-Rich Primer on Pretreated AA2024-T351 in Full Immersion: a Galvanic Throwing Power Investigation Using a Scanning Vibrating Electrode Technique

Kannan

Glover

McMurray

et al. 2018

J. Electrochem. Soc.

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“…120,121 On the other hand, in the case of Mg-rich primers, the corrosion potential of the underlying metal (such as an Al alloy~−0.64 V SCE in 3% NaCl) could also be maintained well below its pitting potential during contact with Mg-rich particles in the primer (~−0.93 V SCE in 3%NaCl). 120,122 The oxides/hydroxides of the active metal particles (with an approximate size of 30-40 µm 122 ) could also serve to provide long-term protection to the underlying metal substrate as reported by Bierwangen et al Indeed, the Mg-rich primer system was reported to provide protection after a 3000 h Prohesion exposure and up to 6000 h under ASTM B117 salt spray testing when a top coat was applied. 120 However, the "self-corrosion" of active metal particles within the primer itself has proven to be a major drawback of metal-rich primer systems.…”

mentioning

confidence: 92%

Chromate replacement: what does the future hold?

Gharbi

Thomas

Smith³

et al. 2018

npj Mater Degrad

175

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The ubiquitous use of chromium and its derivatives as corrosion preventative compounds accelerated rapidly after the second industrial revolution, with such compounds now integral to modern society. However, the detrimental impact of chromium compounds on the environment and human health has prompted the need to revisit the majority of current industrial corrosion protection measures. This review retraces the origins of chromium replacement motivations, introducing the various legislative actions aimed at diminishing the use of chromium compounds, and critically reviews alternative corrosion preventative technologies developed in the recent decades to now. The review, herein, is intended for a broad audience in order to provide a concise update to an increasingly timely issue.

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“…This technique has been exploited with zinc-rich primers on metal surfaces whereby the formation of corrosion product precipitates inside a coating, occur around zinc particles, blocking the pores thereby increasing its barrier resistance [16]. Recently increased attention, particularly from North Dakota State University, has focused on magnesium as a corrosion inhibitor in epoxy primers and some sol-gels for protecting aerospace alloys [17,18,19,20]. The researchers have found that magnesium can provide sacrificial protection and also form a protective oxide layer at the alloy surface thereby enhancing barrier protection.…”

Section: Introductionmentioning

confidence: 99%

Influence of magnesium nitrate on the corrosion performance of sol–gel coated AA2024-T3 aluminium alloy

Varma¹,

Duffy

Cassidy³

2009

Surface and Coatings Technology

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Traditional anti-corrosion technology has relied heavily on using reducible metal species, predominantly hexavalent chromium (Cr(VI)), for protecting reactive metal alloys such as aluminium which is extensively used in the aerospace sector. However, the impending changes in the use of Cr(VI) in Europe and the United States have forced aerospace manufacturers to examine alternative materials for protecting aluminium. One of the most promising alternatives being investigated are organosilane based sol-gels containing anticorrosion additives. In this work the anti-corrosion properties of magnesium (II) nitrate (Mg(NO 3 ) 2 ) as a inhibitor was investigated at different concentrations (0.1% -1.0 wt %) in a methyltriethoxysilane (MTEOS) sol-gel on the aluminium alloy AA 2024-T3 and compared to Alodine TM 1200 (the established Cr(VI) pre-treatment). Electrochemical evaluation of the coating system by electrochemical impedance spectroscopy (EIS) and potentiodynamic scanning (PDS) measurements correlated strongly with results obtained from Neutral Salt Spray (NSS) exposure data. The surface morphology of the coating was studied using atomic force microscopy (AFM) and scanning electron microscopy (SEM). The results indicated the optimum performance was achieved using a Mg (NO 3 ) 2 . level of 0.7% w/w. It is proposed that the superior anticorrosion properties of the Mg 2+ rich sol-gel is due to the pore blocking mechanism of insoluble Mg(OH) 2 formed during the hydrolysis process.

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Electrochemical behaviour of a Mg-rich primer in the protection of Al alloys

Cited by 136 publications

References 14 publications

Performance of a Magnesium-Rich Primer on Pretreated AA2024-T351 in Full Immersion: a Galvanic Throwing Power Investigation Using a Scanning Vibrating Electrode Technique

Performance of a Magnesium-Rich Primer on Pretreated AA2024-T351 in Full Immersion: a Galvanic Throwing Power Investigation Using a Scanning Vibrating Electrode Technique

Chromate replacement: what does the future hold?

Influence of magnesium nitrate on the corrosion performance of sol–gel coated AA2024-T3 aluminium alloy

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