Abstract
In order to examine the relationship between the microstructure and the corrosion behavior in chloride solution, the microstructure of AlSi10Cu (Fe) sand cast aluminum alloy has been investigated by using different techniques including scanning electron microscopy, energy-dispersive spectroscopy, X-ray diffraction analysis and electrochemical measurements. The microscopic analysis and X-ray diffraction analysis show several phases in addition to matrix phase, including pores and phases at nano- and microscales. The average rate of micropores and nanopores is 4% and 5%, respectively. The nanoparticle size varies between 20 and 150 nm. Plates and corals-like silicon eutectic, rich-Cu phase and Chinese script phase (Al15(Mn,Fe)3Si2) have been observed. Energy-dispersive spectroscopy analyses show the presence of a new phase (Cu61.22 Zn25.39Ni11.85 Al1.54), and the pitting corrosion has been demonstrated to be initiated at the nanopores. The electrochemical measurements exhibited the effect of several elements and porosities on the corrosion kinetics that is controlled by charge transfer and diffusion phenomenon. Wide passive windows, followed by the breakdown of passive film and excessive dissolution, have been observed in 0.3 and 3 wt% NaCl solutions. The electrochemical measurements show a high corrosion rate which does not recommend the use of this alloy in seawater.
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Introduction
Aluminum alloys are chosen as materials for construction in various fields due to their low density and their high corrosion resistance (Singh and Goel 1990). The aluminum–silicon alloys are economical and more lightweight due to the high quantity of silicon (Ahn et al. 2018). However, a high ratio of silicon in aluminum alloys can increase the cracking, the wear resistance and the fluidity of these alloys. Moreover, it can minimize the shrinkage porosity and reduce the melting temperature point (Ahn et al. 2018; Elzanaty 2015). Therefore, the use of these alloys is limited due to the variations of their properties and their limited performance, especially at high temperature (Stadler et al. 2011, 2012; Ceschini et al. 2015).
The mechanical properties of these alloys depend on their microstructure, their chemical composition and their defects (Zamani et al. 2015; Campbell and Castings 2003; Jiang et al. 2014). In order to enhance their properties, some metallic elements including Mg, Cu, Fe, Ni and Sr have been added in addition to the silicon. In fact, the alloys microstructure is characterized by various present parts such as α-aluminum phase, primary silicon particles, aluminum–silicon eutectic, intermetallics and precipitates (Tenekedjiev and Gruzleski 1990; Bogdanoff et al. 2016).
The coral-like eutectic structure can be obtained by heat treatment or by addition of low concentrations of elements such as Na, Sr, or Eu which change the silicone plate-like eutectic morphology to fine and round coral-like eutectic morphology (Barrirero et al. 2019).
The α-aluminum phase represents the matrix of cast aluminum–silicon alloys; it crystallizes in the appearance of non-faceted dendrites (Warmuzek 2004) and sometimes in appearance of non-dendritic forms (Zazi 2013). Moreover, the hard primary silicon particles distributed in the matrix are responsible for the good mechanical properties and the high wear resistance (Elzanaty 2015). (Oya et al. 2013) showed that the intergranular corrosion susceptibility increases as a function of the silicon content in the alloys.
Aluminum–silicon–magnesium alloys are polyphase materials and have good properties such as excellent castability, high ductility, high strength and low thermal expansion coefficient (Ahn et al. 2018; Cáceres et al. 2003). These properties explain why these alloys have occupied an important position in the field of automobile applications and are widely used in the production of engine components. The mechanical properties of these alloys depend on the size, the shape, the distribution, the degree of modification of eutectic phase, and the primary silicon particles (Ye 2003; Ma et al. 2017; Mohamed and Samuel 2012; Al-Hella and Kawther 2013). Moreover, the casting process plays a crucial role in the microstructure and mechanical properties of these alloys (Al-Hella and Kawther 2013).
In aluminum–silicon–magnesium cast alloys, the Mg-containing phases formed during the solidification are Mg2Si, Si eutectic crystals and the π-Fe phase. The contents of Mg and Fe in these alloys and the solidification rate determine the fractions of the β-Fe and π-Fe phases and the concentration of Mg in solid solution. The π-Fe phase has a Chinese script or blocky morphology, and it is often formed on the β-Fe plates. The Mg2Si phase ratio increases with the Mg content in the alloys, i.e., from close to zero for 0.3 wt% Mg to 0.2 vol% for 0.7 wt% Mg (Sjölander and Seifeddine 2010). The secondary phases, including Mg2Si, π-Fe, β-Fe and Si eutectic crystals, can induce specific alloy properties and therefore have an influence on the mechanical and corrosion behavior of these materials (Dobkowska et al. 2016; Cecchel et al. 2017). In aqueous media, the corrosion resistance of aluminum and its alloys is provided by the formation of an oxide film composed of Al2O3, Al(OH)3 and AlO(OH) phases on the metallic surface (Barr 1977). However, for media containing chloride ions, an extensive localized attack or a uniform corrosion can be observed (Bessone et al. 1992; Munoz and Bessone 1999; Allachi et al. 2010; Zazi et al. 2010). The oxide film on aluminum surface is a poor electronic conductor, and the cathodic reactions take place on the micron size intermetallic particles or smaller precipitate particles (Zaid et al. 2008). The silicon-rich phase can cause galvanic corrosion, and the porosities formed during the casting processes can generate crevice corrosion (Dobkowska et al. 2016)].
Several authors have showed the presence of Al2Cu phase during the solidification of aluminum–silicon–copper alloys (Sjӧlander and Seifeddine 2010; Dobkowska et al. 2016; Cecchel et al. 2017; Barr 1977; Bessone et al. 1992; Munoz and Bessone 1999; Allachi et al. 2010; Zazi et al. 2010; Zaid et al. 2008; Djurdjevic et al 1999; Samuel et al. 1997; Li et al. 2003). This phase can be found in different shapes as compact block-like phase type, eutectic Al2Cu phase type or mixture of both types. This Al2Cu phase arises from β-Fe plate’s phase or on coarse eutectic Si particles phase during the end of solidification process. Other phases including ß-Mg2Si, Ө-Al2Cu, π-Al8Mg3FeSi6, Q-Al5Cu2Mg8Si6, α-Al15(Fe,Mn)3Si2 and ß-Al5FeSi can also be present in the alloys (Zazi et al. 2010; Li et al. 2003; Dinnis et al. 2006).
Porosities are cavities which are formed during the metal solidification. They are regarded to be the first defect that occurs in aluminum–silicon casting alloys (Ammar et al. 2008). These porosities can cause various issues such as poor mechanical properties with limited strength and ductility, variable fracture toughness and crack initiation sites (Ammar et al. 2008). The porosity development in solidifying aluminum–silicon casting alloys is due to shrinkage resulting from volume contraction associated with the solidification, and the entrapment of gas (mostly hydrogen and air) resulting from a decrease in gas solubility in the solid alloy compared to the liquid (Ammar et al. 2008). The formation of microporosities during the solidification of aluminum alloys is responsible for problems in the production of good quality products. Moreover, the process parameters during the solidification have a significant effect on the microstructural development of the alloy and determine the final engineering performance of the casting. Other parameters such as dendrite segregation, nature, size, distribution and morphology of precipitates and porosities have also a significant influence on mechanical and chemical alloys properties (Ferreira et al. 2010; Kuchariková et al. 2020).
The present work is a part of a larger research project (corrosion of AlSi cast alloys), which was performed to examine and to offer a better understanding of the influence of porosities (nano and micro size) and intermetallics on the corrosion behavior of AlSi10Cu(Fe) sand cast alloy containing zinc and to find the relationship between the microstructures and the corrosion behavior. The study has been achieved by investigation of microstructure of AlSi10Cu(Fe) sand cast aluminum alloy before and after two weeks of immersion in chloride solution (0.3 and 3 wt% NaCl) at room temperature and correlation with the observed corrosion phenomenon.
The microstructure was investigated by using optical microscopy, scanning electron microscopy (SEM), energy-dispersive spectroscopy (EDS), X-ray diffraction (XRD) and electrochemical measurements.
Experimental
Materials
The investigation materials were a hypoeutectic aluminum sand casting alloy AlSi10Cu(Fe), and the experimental samples were prepared from an industrial ingot from SNVI company (Aluminum Foundry Unit, Rouiba), Algeria.
The chemical composition of the alloy is shown in Table 1. The casting was carried out by gravitation in sand mold at temperatures between 700 and 750 °C.
The samples were cut into cubic form from the ingot by using a mechanical saw.
Alloy elaboration
The elaboration has been carried out by the use of melting and maintenance furnaces, and casting pockets with capacities of 350 kg, 150 kg and 50 kg, respectively.
A mixture of 160 kg of AlSi10Mg ingots with dimension of (720 × 100 × 80) mm3 delivered by PECHINEY added to 190 kg of returns (Runners, channels of casting, defective and rejected parts… etc.) was melted at a temperature between 700 and 750 °C, then cleaning and creaming were carried out, afterward the liquid mass was subjected to a degassing treatment, and finally the liquid metal was cast in the maintenance furnace at 750 °C, where the refining operation and a second cleaning were performed. 15 kg of the liquid metal has been cast in a casting pocket and then in sand molds. The obtained ingot was in dimensions of 300 × 100 × 60 mm3. No chemical composition correction, in the liquid mass, has been done during sand cast alloy elaboration.
Sample preparation and microstructure characterization
Metallographic observations were performed using optical microscopy. The samples were prepared by means of the standard metallographic procedure as follows: The samples were polished with emery paper from 600 to 4000 grit and then degreased with ethanol (from SIGMA ALDRICH Company, with purty ≥ 99.8%), cleaned with distilled water and finally dried in air. The etching process was performed in the solution composed of 99.9 in wt% H2O (Monodistilled) and 0.1 in wt% NaOH (from SIGMA ALDRICH company, and purity ≥ 98.8%).
The sample surfaces were observed by optical microscopy and scanning electron microscopy before and after immersion during two weeks in aerated chloride solution of 0.3 wt% Microstructural analyses of the samples were carried out using a metallurgical microscopy (Carl Zeiss ICM405 microscopy) and a scanning electron microscopy (FEG Zeiss Ultra 55) equipped with an energy-dispersive spectrometer EDS (Brüker EDS Quantax).
The X-ray diffractograms of the materials were determined by XPERT PRO X-ray diffractometer at ambient temperature. The analyses of diffractograms (identification of aluminum peaks and intermetallic phases) were made by means of High Score software.
Electrochemical measurements techniques
The electrochemical measurements for 1.13-cm2 samples immerged in sodium chloride solution 0.3 and 3 wt% NaCl at room temperature have been carried out. Using a potentiostat/galvanostat GAMRY Reference 600+ controlled by software GAMRY Framework. Input current /voltage range are 60 pA to 600 pA, − 24 to + 24 V, respectively.
A classic three-electrode method has been used. The reference electrode was a saturated calomel electrode (SCE); the auxiliary electrode was a platinum grid (3-cm2).
Potentiodynamic polarization tests have been undertaken with a scanning rate equal to 1 mV/s from − 1.2 to − 0.2 V according to the reference electrode.
The electrochemical impedance spectroscopy measurements was carried out in a frequency range from 100 kHz to 1 mHz and with a 10 mV potential modulation amplitude. To obtain accurate electrochemical impedance values, integration has been performed for seven cycles.
Results and discussion
The characterization of polished cast AlSi10Cu(Fe) aluminum alloy, both etched and non-etched samples, using optical microscopy is shown in Fig. 1. As it can be observed, the cast AlSi10Cu(Fe) aluminum alloy is characterized by a dendritic structure of the α-aluminum solid solution phase and two forms for the aluminum–silicon eutectic (silicon plate-like eutectic and coral-like eutectic). Firstly, unmodified silicon eutectic (silicon plate-like eutectic) is observed as it is for industrial solidifying conditions. Secondly, a modified coral-like eutectic phase is distributed over the entire sample surface with a low density as it is visible in Fig. 1e. Other secondary phases in the microstructure of the aluminum alloy such as rich-Cu phase and Chinese script phase Al15(Mn,Fe)3Si2 have been observed (Fig. 1). In order to identify the types of phases, EDS analysis has been used.
Micrographs of sand casting aluminum alloy AlSi10Cu(Fe) are shown in Fig. 2. For all figures, presence of pores and phases has been observed at micro- and nanoscales. The identified phases are α-Al matrix and Al-Si eutectic which appeared in the interdendritic space and intermetallic compounds.
The observed micro- and nanopores are due to hydrogen gas arising during melt casting because of a low speed cooling in sand casting: Hydrogen gas remains in the solidified melt in pores and micro-shrinkages, as described by (Michna et al. 2007). On the other hand, some pores are due to the effect of iron castability in AlSi10Cu(Fe) alloy; as reported by several authors (Taylor 1995; Mbuya et al. 2003; Roy et al. 1996), iron may degrade the castability of the alloys and an increase in iron content in alloy generates an increase in porosities rate. Moreover, the formation of iron-rich intermetallic phases can lead to the formation of shrinkage and porosity defects (Taylor 2004; Berlanga-Labari et al. 2020). An increase in iron content in alloys leads to an increase in hydrogen gas pressure in equilibrium, which is related to a given rate of dissolved gas. Moreover, the iron β-Al5FeSi phase can provide pore nucleation sites (Mbuya et al. 2003; Roy et al. 1996). In our case, the mass percentage of iron in the alloy is equal to 1.21 wt% and the solubility of iron in the aluminum matrix is very low, i.e., 0.04 wt at 655 °C, and less than 0.01 wt% at room temperature. As a result, several iron-rich intermetallic particles can form during solidification, leading to the formation of porosities in the alloys. Other phases, Al2Cu and sludge for example, restrict pore growth and expansion (Roy et al. 1996). It should be noted that the nanopores were only observed at the surface of the matrix.
As described in the literature (Tillov et al. 2012), the size of micro- and nanoparticles and the morphology of intermetallic phases depend on various parameters such as chemical composition, solidification conditions and particularly heat treatment process. The used AlSi10Cu(Fe) cast aluminum alloy samples have not undergone heat treatments, leading to the presence of micro and nanoporosities with an average rate of 4% and 5%, respectively. The size of the observed nanoparticles varies between 20 and 150 nm.
SEM images associated with EDS spectra and chemical composition of a polished AlSi10Cu(Fe) cast aluminum alloy sample before immersion in chloride solution, for three zones, are shown in Figs. 3, 4, 5 and Tables 2, 3, 4, respectively. These figures show the matrix phase, the eutectic phase and different other secondary phases and particularly numerous chemical compositions for each secondary phase. These figures and the EDS spectra highlight that the samples are multicomponent aluminum alloys with various elements (Al–Si–Cu–Fe–Mn–Mg–Zn–Ni). The details of chemical composition for each sample are shown in Tables 2, 3 and 4.
According to the literature, these elements have a low solubility at room temperature but in this case, their concentrations in the alloys are higher than their solubility in aluminum at ambient temperature (Mathers 2002; Reardon 2011; Ambat et al. 2006; McAlister and Murray 1987; Bannour et al. 2013; Skoko et al. 2009; Jia et al. 2018). It means that equilibrium is not reached; these elements may also exist in supersaturated solid solutions or in non-equilibrium intermetallic phases (Mathers 2002).
In Al-Si alloy, Al-Si multicomponent alloys or commercial and hypoeutectic alloys, several phases such as Al2Cu, Mg2Si, α-Al12(Fe,Mn)3Si2, β-Al5FeSi, etc., have been reported by (Mbuya et al. 2003). In this work, a new phase Cu61.22Zn25.39Ni11.85Al1.54 has been evidenced, as it can be observed in Fig. 4 and Table 3.
The Fe containing insoluble phases can take place in different forms including large or small needles or platelets, Chinese script, spheroidal or globular, rosette-like, polygonal, hexagonal, polyhedral, star-like, clusters. Other shapes can also be observed, for examples π-Al8Mg3FeSi6 in a Chinese script morphology, Al5FeSi as needles, β-Al5FeSi in platelet form, All5(Fe,Mn)3Si2 in polyhedron forms, [Al15(Fe,Mn,Cr)3Si2] in sludge form (Mbuya et al. 2003; Roy et al. 1996; Taylor 2004; Tillov et al. 2012). The large number of phases, the multicomponent aspect and the differences in the composition, form and phase size, for the aluminum–silicon alloys, do not facilitate the study of the corrosion behavior of these alloys.
Figure 6 shows the X-ray diffractogram of the aluminum AlSi10Cu(Fe) sand cast alloy. The aluminum peaks are observed in the diffractogram (Fig. 6a). All seventeen phases present in the alloy are shown in Fig. 6b and listed in Table 5. Three phases (7, 10 and 15) contain zinc, the phase (7) is close to the phase observed by EDS as described in Table 3 and Fig. 4, which confirms the presence of the Cu61.22Zn25.39Ni11.85Al1.54 phase.
Figures 7, 8, 9, 10 and 11 show the SEM images for several zones of AlSi10Cu(Fe) sand casting aluminum alloys, immersed in 0.3 wt% NaCl solution during two weeks. The corrosion morphology of the material after immersion in chloride solution is very complex. Independently of the contact between the second phases and the matrix, it seems that the generalized corrosion is extended over the matrix phase, as shown in Figs. 7d, e, 9a, b, 10c, d and 11a–c. The presence of second phases on the surface of the alloy promotes the formation of microgalvanic cells between the matrix and the second phases resulting in the corrosion of the matrix surrounding the seconds phases (Figs. 7d, e, 9a, b, 10a, b and 11b, c, e) or in the dissolution of seconds phases (Figs. 7a–c, 10c, d and 11b, c). The corrosion occurring on the matrix surrounding the second phases is due to the higher corrosion potential of the existing phases, as Al2Cu(θ), AlFeMnSi, AlCuFeMn, AlCuFeSi and (Al,Cu)x(Fe,Mn)ySi, and the more active aluminum matrix. According to the work of Birbilis and Buchheit (2005), the cathodic nature of these intermetallic phases compared to the matrix causes the reaction of oxygen reduction on the intermetallic particles surface, leading to the formation of hydroxide ions. At the same time, a local increase in pH takes place, which provides a breakdown of the flimsy oxide film and the dissolution of the area surrounding the intermetallic particles phases. The presence of iron, copper and nickel in intermetallic phases has a determinant effect on the alloy resistance in chloride solution (Ambat et al. 2006; Seri et al. 1989; Hossain et al. 2015). The dissolution of intermetallic particle phases, and/or less noble segregated elements, is characterized by a perforation encircled by white circles, surrounding the β-Fe plate phases, as observed in Fig. 11f. In this case, the dissolved intermetallic particles are less noble than the surrounded phases and the matrix phases, and the same phenomenon occurs between the nobler phases (matrix and surrounded phases) and the dissolved phase. According to Birbilis and Buchheit (2005), this can be due to the fact that the dissolved phases contain one, two or all elements which are contained in the alloy, including zinc, magnesium and manganese.
The dissolution of the α-aluminum phase in silicon eutectic is shown in Figs. 7a–c, 10b–d and 11a–c. This dissolution can be explained by the potential difference between α-aluminum phase and silicon phase since the silicon phase potential is always higher than the α-aluminum phase potential in chloride solution (Birbilis and Buchheit 2005).
Figure 9 shows the formation of several hemispherical pits in certain zones or only one pit in other zones. The authors observed also a localized corrosion with crater shape in the nanopores of the matrix phases (Fig. 8). We assume that the pit beginning occurs at nanopore level.
Small white 50–200 nm size intermetallic particles can be observed in Figs. 7b–d, 10c, d and 11e, f. Particles of approximately50 nm size were observed on the silicon plates-like eutectic (Fig. 7b, c) and coral-like eutectic phases (Fig. 7d). These particles were not dissolved after two weeks of immersion in chloride solution, meaning that their corrosion potential is higher than those of all other present phases.
SEM images associated with EDS spectrum and chemical composition of AlSi10Cu(Fe) cast aluminum alloy after two weeks of immersion in chloride solution are shown in Fig. 12 and Table 6, respectively. Two points (a and b) in zone 6 have been chosen in the areas adjacent to the pits.
We observe the presence of oxygen, magnesium, aluminum, chlorine, carbon and oxygen in point a, and aluminum, silicon, magnesium and chlorine in point b. This result is in accordance with (Yoo et al. 2011). Moreover, the formation of a homogeneous layer of hydrated aluminum oxide surrounding the pit has been identified, confirming a pitting corrosion mechanism. In fact, hydrated and dehydrated aluminum oxides can be formed when aluminum is exposed to a solution containing aggressive ions, as in our case (Pourbaix 1974). The EDS analyses showed also the presence of carbon traces.
Electrochemical analyses including current–potential curves and electrochemical impedance spectroscopy of AlSi10Cu(Fe) sand cast alloy immersed in 0.3 and 3 wt% NaCl solutions for different times are shown in Figs. 13, 14, 15, 16, 17, 18, 19, 20 and Tables 7, 8, 9, 10.
Figure 13 shows difference in corrosion kinetics between the first hour of immersion and after two weeks of immersion in a 0.3 wt% NaCl solution. A large decreasing of corrosion potential was observed, from − 0.583 V after 1-hour immersion to about − 1.09 V after two weeks. Moreover, a weak increase in polarization resistance is observed after two weeks, i.e., from 2.5 kΩ to 2.8 kΩ (Table 7). In Figs. 14 and 15, we observe a huge corrosion potential decrease from − 0.583 to − 1.140 V, between 1-h and 7-day immersion, followed by a corrosion potential increase up to − 1.097 V after two weeks of immersion. A large increase in polarization resistance was observed between 1- and 24-h immersion, from 2.5 to 16.5 kΩ, thereafter a decrease until 7 days, from 16.5 to 2.1 kΩ, and finally an increase to 2.8 kΩ after 14 days (Table 7). The variations in corrosion potential and polarization resistance are due to an oxide layer formation and the dissolution of noble metals on the alloy surface.
The corrosion rate is determined using the following relation (Rossi et al. 2007):
where A is material molar mass (g/mol.), icorr current corrosion density (µA/cm2), n exchanged electrons number, and F Faraday constant = 96500C, ρ Density of metal (g/cm3).
The corrosion rate increases from 0.043 mm/year after 1 h of corrosion to 0.274 mm/year after 7-day immersion and decreases to 0.172 mm/year after 2 weeks.
Wide passive zones, followed by the breakdown of passive film and excessive dissolution, were observed after corrosion during three, seven days and two weeks, and their values are ~ 570 mV, ~ 544 mV, ~ 500 mV, respectively (Fig. 14).
The corrosion behavior of the alloy is similar in 3 wt% NaCl solution. Figures 16, 17 and 18 show a difference in corrosion kinetics between the first hours until two weeks of immersion. A large corrosion potential decrease is observed, from − 0.935 V after one hour and − 1.105 V after one week, and then an increase to − 1.092 V after two weeks. The polarization resistance decreases from 21 kΩ after 1 h of immersion to 0.5 kΩ after 3 days of corrosion and then increases up to 1.4 kΩ after two weeks (Table 8). The corrosion rate increases from 0.017 mm/year after 1 h of immersion to 0.466 mm/year after one week. Due to this high value, the use of this alloy is not recommended for seawater.
The increase in NaCl concentration in the solution greatly modifies corrosion potential values and polarization resistances during the first hour of immersion. In both cases, the polarization resistance is the highest at the first hour and the corrosion potential converges to the same value after two weeks of immersion. The modification of the corrosion kinetics is probably due to pitting corrosion phenomenon (Figs. 9, 10), appearance and disappearance of microporosities and nanoporosities on the surface, presence of less noble elements segregated or not and particles dissolution as a function of the immersion duration.
Wide passive windows, followed by the breakdown of passive film and excessive dissolution, were observed after twenty four hours, three days, seven days and two weeks of corrosion with values equal to ~ 429 mV, ~ 465 mV, ~ 493 mV, ~ 470 mV, respectively (Fig. 18).
Figure 19 shows the Nyquist plots of impedance of the alloy immersed in 0.3 wt% NaCl solution. In all diagrams, a charge transfer loop at high frequency followed by a diffusion phenomenon at low frequency is observed; the result is in good agreement with (Frers et al.1990, Jafarzadeh et al. 2009 and Fernandes et al. 1989). The charge transfer loop is directly related to electrochemical transfer reactions, typically due to the metallic dissolution occurring on the alloy surface, for example:
and,
The transfer resistance value increases with immersion time, from 554 Ω after one hour to 2768 Ω after two weeks of immersion (Table 9).
The diffusion (Warburg) line is representative of the transport phenomenon, toward the porous surface layer of the alloy.
An analysis of the high-frequency loop allows determining the double-layer capacitance and transfer resistance values. The double-layer capacitance Cd values are not constant according to the immersion times (Table 9); this is probably due to an evolution of the passive layer thickness on the alloy surface, the localized corrosion process, and the presence of porosities. The increase of the transfer resistance value can be explained by the increase in the oxide layer thickness (Zazi et al. 2010).
The impedance spectra of AlSi10Cu(Fe) sand cast aluminum alloy immersed in 3 wt% NaCl solution are presented in Fig. 20, and the characteristics of the impedances curves are given in Table 10. As for the previous case, the diagrams show a charge transfer loop, followed by a diffusion phenomenon. The charge transfer resistance (Rt) increases with immersion time, from 271 Ω after one hour up to 2536 Ω after two weeks of immersion. However, the double layer capacitance (Cd) values decrease from 587 µF after one hour up to 323 µF after two weeks of immersion.
Conclusions
The present work was performed to examine and to offer a better understanding of the influence of several intermetallics and porosities (nano and microporosities) on the corrosion behavior of AlSi10Cu(Fe) sand cast alloy containing zinc and to find the relationship between the microstructure and the corrosion behavior. Microstructure characterization and corrosion behavior of aluminum AlSi10Cu(Fe) sand cast alloy in chloride solution were investigated. The main results can be summarized as.
The chemical composition of the different second phases present in the alloy is variable, several phases and a new phase Cu61.22 Zn25.39Ni11.85 Al1.54, white nanoparticles on a silicon plate-like eutectic and coral-like eutectic have been observed.
Dissolution of aluminum phase surrounding the eutectic phases, and dissolution of fine particles and/or segregation surrounding the β-Fe plates phases occur. Nanopores on the surface of the samples have been characterized and can be responsible for the pitting corrosion, and the analysis of pitting zones shows that the zones contain oxygen, aluminum, silicon, magnesium and chlorine.
The Nyquist plot evidences a charge resistance transfer at high frequency followed by a diffusion phenomenon (Warburg line) at low frequency. Impedance measurements show dissolution of metals on the alloy and electrolyte diffusion toward the porous surface layer of alloy, without adsorption phenomenon. It can be assumed that the corrosion phenomena are due to the appearance and the disappearance of porosities and the dissolution of less noble elements.
The transfer resistance is about 2.7 kΩ in 0.3 wt% NaCl and 2.5 kΩ in 3 wt% NaCl after two weeds of immersion, and the double-layer capacitance is about 200 µF in the 0.3 wt% NaCl solution and 300 µF in 3 wt% NaCl solution after 14 days of corrosion. An increase in the transfer resistance and a change of the double layer capacitance with increasing immersion duration were observed. The change of double layer capacitance can be due to the presence of porosities on surface. The corrosion potential tends to − 1.10 V after 14 days of corrosion in 0.3 and 3 wt% NaCl solutions. The polarization resistance is about 2.8 kΩ in the 0.3 wt% NaCl solution, and 1.4 kΩ in the 3 wt% NaCl solution. Due to its high corrosion rate value, in the 3 wt% NaCl solution, the use of the alloy in sea water is not recommended. Wide passive windows, followed by the breakdown of passive film and excessive dissolution, were observed in 0.3% and 3 wt% NaCl solutions.
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Korichi, B., Zazi, N., Delbrel, S. et al. Microstructural, morphological characterization and corrosion behavior of sand cast AlSi10Cu(Fe) alloy in chloride solution. Chem. Pap. 76, 2947–2967 (2022). https://doi.org/10.1007/s11696-022-02064-9
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DOI: https://doi.org/10.1007/s11696-022-02064-9