ap-4-12.dvi Acta Polytechnica Vol. 52 No. 4/2012 Strontium As a Structure Modifier for Non-binary Al–Si Alloy Barbora Brykśı Stunová1 1 CTU in Prague, Faculty of Mechanical Engineering, Department of Manufacturing Technology, Technická 4, 166 07 Prague, CZech Republic Correspondence to: barbora.stunova@fs.cvut.cz Abstract This paper presents a study of the influence on the structure of AlSi10Mg alloy when 400 ppm of strontium is added. Not only changes in the morphology of eutectic silicon, but in particular changes in the morphology of the intermetallic phases are monitored, namely phases containing iron and magnesium. The effect of strontium on structural defects, namely cavities formation, is also observed. It was found, that in non-binary system Al–Si–Mg also intermetallic phases of magnesium are affected by addition of strontium: especially phase Mg2Si changes the morphology significantly from unmodified to modified structure. Moreover, findings of other authors, that strontium has a negative effect on the level of gas porosity and on the distribution of shrinkages, are also confirmed. Keywords: strontium, aluminum alloys, structure, structural defects. 1 Introduction In the foundry industry, strontium is used as a mod- ifier element. When it is added, eutectic crystalliza- tion is affected in order to improve the mechanical properties, especially ductility, see e.g. [1]. Find- ings of authors in recent years [2–6] show, that mod- ification elements, including strontium, besides the change in morphology of eutectic silicon, also affect intermetallic phases. In this regard, interesting find- ings with iron have been published. Iron as a nega- tive element creating undesirable intermetallic phases in Al–Si alloys is commonly compensated in practi- cal applications by the addition of manganese, which helps to create intermetallic phases with a more fa- vorable morphology (skeletal “Chinese script”). It was proven by other authors e.g. [2,5] that the mor- phology of iron intermetallic phases can be influenced by adding strontium. These authors usually exam- ined binary alloys with the addition of iron, or alloys containing copper. Other authors [1] describe the influence of stron- tium modification on structural defects of Al–Si al- loys, which mainly involve shrinkage and gas porosity, often a combination of the two phenomena. Gener- ally, strontium has a negative influence on structural defects, such as cavities. The aim of this work was to perform a complex experiment with non-binary Al-Si alloy modified by strontium, with the following goals: • to observe the modification effect of various modification agents containing strontium in var- ious amount • to confirm the influence of strontium on inter- metallic phases containing iron for specific non- binary alloy • to observe the influence of strontium on other in- termetallic phases present in specific non-binary Al–Si alloy • to confirm the influence of strontium on struc- tural defects of a non-binary alloy • to compare the effect of different modification agents containing strontium in various amounts on the factors mentioned above • to compare the structural changes with the un- modified structure • to analyze the results and formulate the theoret- ical consequences. 2 Theoretical background The modification effect of strontium on the morphol- ogy of eutectic silicon is widely known, and is widely used in foundry practice. However, the principle is still not satisfactorily explained. One of the most ac- cepted theories for explaining the modification prin- ciple is the IIT mechanism (Impurity Induced Twin- ning) e.g. [1]. However, recent studies have shown that modification changes the nucleation frequency and dynamics of eutectic grains, with associated ef- fects on the growth rate. In unmodified commercial Al-Si alloys, a large number of eutectic grains nucle- ate at or near the primary aluminum dendrite tips, and eutectic aluminum forms epitaxially on the pri- mary dendrites. On the other hand, with addition of eutectic modifiers, i.e., Sr, a dramatic decrease in the nucleation frequency of eutectic grains is observed, and the grains are nucleated independently of the primary phase at distributed centers in the interden- dritic regions. The eutectic reaction in Al–Si alloys commences with the nucleation of the silicon phase, 26 Acta Polytechnica Vol. 52 No. 4/2012 which is the leading phase during growth of the Al– Si eutectic. Aluminum phosphide (AlP) particles are very potent nuclei for eutectic silicon in commercial Al-Si alloys, where phosphorus is commonly present as an impurity element. The addition of sodium neu- tralizes AlP and thus makes nucleation of eutectic silicon more difficult. More recent studies of eutectic nucleation have confirmed that AlP nucleates eutec- tic silicon and the large reduction in nucleation fre- quency of eutectic grains in Sr-modified Al–Si alloys appears to be caused by some poisoning mechanism of the potent nuclei. [2] In addition to the effect of Sr addition on the growth of eutectic Si, recent studies have confirmed that Sr also significantly changes the nucleation behavior of the eutectic phases. It is pro- posed that the addition of Sr deactivates AlP and/or oxide bifilms as favored nucleation sites for eutectic Si. Thus, Si is forced to nucleate at a lower tempera- ture on some unknown substrate and grow as a fine, fibrous eutectic Si with high twin density. In order to confirm one of the proposed mechanisms, there is great interest in analyzing the local distribution of the modifying element within the Al-Si eutectic and at the Al/Si eutectic interfaces. [3] The modification may also affect the morphology of undesirable intermetallic phases, e.g. phases con- taining iron. As in the example in [2,4–6], some mod- ifier elements, e.g. strontium and potassium, have a positive effect on the morphology of β-Al5FeSi, or on the conversion of this phase to the α-Al8Fe2Si phase. The available literature does not satisfacto- rily describe the relationship and influence of stron- tium and magnesium. Some studies have identified magnesium as an element that facilitates the modi- fication, while other studies have attributed to mag- nesium a negative effect on modification. However, no studies have been carried out on the effect of strontium on the morphology of intermetallic phases containing magnesium. In Al-Si alloys, magnesium is usually found as the Mg2Si phase, but it may also be present in iron-containing phases such as the FeMg3Si6Al8 phase, or in other complex eutec- tics. Modification elements may have not only a pos- itive structural influence, but also a negative effect, manifested by an increase in porosity. One considera- tion is porosity due to hydrogen. Another important aspect of the modification, however, is the change in the solidification temperature range. The modifica- tion may cause changes in the model of shrinkage, and may cause gas porosity. Experiments performed by other authors have shown that total shrinkage, which is an alloy property, is not at all affected by modification. However, the way in which this shrinkage is distributed between macro-piping and microshrinkage depends strongly on whether or not the alloy is modified. Both sodium and strontium cause a significant diminution of the primary pipe and an increase in the amount of microporosity. In other words, shrinkage is redistributed when modifi- cation occurs. [1] 3 Experimental Non-binary EN AC-43100 (AlSi10Mg) alloy was cho- sen for the experiment (for chemical composition, see tab. 1). The batch consisted only of alloy ingots, with no recycled material. The melt was neither refined nor degassed. The samples were cast in a green sand molding mixture, with 4 casting samples in one mold. The reference samples were cast with- out modification. 400 ppm of strontium was added to the modified samples in the form of the following five modification agents: AlSr3.5, AlSr5, AlSr10 pre- alloys — all wrought, AlSr10 cast pre-alloy and pure strontium. Samples for metallography were taken from the castings, and the chemical composition of the samples was measured (Table 2). Table 1: Standard prescribed chemical composition of experimental alloy AlSi10Mg alloy/element Si Fe Cu Mn Mg Ni Zn Ti Al EN AC-43100 (AlSi10Mg) 9–11 0.55 0.10 0.45 0.20–0.45 0.05 0.10 0.15 remainder Table 2: Resultant measured chemical composition of casting samples agent/element Si Fe Cu Mn Mg Ni Zn Ti Sr P Al unmodified 10.304 0.304 0.032 0.230 0.398 0.005 0.078 0.055 0 0.006 88.496 AlSr3.5 10.337 0.311 0.024 0.153 0.362 0.006 0.098 0.076 0.037 0.006 88.511 AlSr5 10.627 0.327 0.022 0.156 0.332 0.006 0.093 0.077 0.044 0.006 88.225 cast AlSr10 10.177 0.254 0.040 0.320 0.402 0.002 0.037 0.024 0.031 0.006 88.613 wrought AlSr10 10.247 0.246 0.041 0.318 0.412 < 0.002 0.035 0.024 0.044 0.006 88.532 pure Sr 10.689 0.259 0.025 0.163 0.337 0.005 0.086 0.071 0.018 0.006 88.259 27 Acta Polytechnica Vol. 52 No. 4/2012 4 Results The metallography provided some interesting find- ings. On closer examination, the eutectic grain boundary areas show coarse eutectic silicon. In addi- tion, these sites contain coarse intermetallic phases, in particular iron, iron and manganese and magne- sium phases (Figure 1). Figure 1: AlSr3.5 modified sample — characteristic intermetallic phases at grain boundaries, 200×, 1 – phase of iron, probably β-Al5FeSi, 2 – phase of iron and manganese, probably Al15(FeMn)3Si2, 3 – phase of magnesium Mg2Si A spectral analysis of selected phases was per- formed to confirm the assumptions presented above about the composition of the intermetallic phases at the grain boundaries. It turned out that magnesium is also present in the phases that were assumed to be of Al(FeMn)Si type. Figure 2 shows a detail of connected intermetallic phases. Position Spectrum 1 was defined as the phase where, in addition to alu- minum and silicon, chromium also occurs, and espe- cially manganese and iron in the order of units to tens of percentage points. In addition to what is indicated above, Spectrum 3 shows a content of 1.32 wt. % of magnesium. Besides the aluminum and silicon con- tent, positions 2 and 4 also have around 6 wt. % mag- nesium, 4 wt. % iron, but very little or no manganese content. Similarly, Figure 3 shows a phase containing mag- nesium (12 %), iron (4.3 %) and manganese (0.83 %) as position 1. Position 2 is the eutectic silicon phase. Position 3 is rich in magnesium and silicon, while the morphology may be considered as an Mg2Si phase, confirming the original assumption. When comparing the different structures obtained by the modifying agents, various morphologies of the various intermetallic phases and cavity structural de- fects can be observed. Figure 2: Detail of intermetallic phases of modified structure from electron microscopy and spectral ana- lysis Figure 3: Detail of intermetallic phases of modified structure from electron microscopy and spectral ana- lysis Figure 4: Unmodified structure, mag. 1 000× An unmodified structure (Figure 4) contains the primary dendrites of the solid solution and 28 Acta Polytechnica Vol. 52 No. 4/2012 the coarse eutectic, intermetallic phases of iron, which are of acicular to skeletal character, while the branches of these particles are quite massive. Oc- casionally there are skeletal particles of magnesium phase Mg2Si, always tied to the eutectic silicon or iron phase. The magnesium phases are often frag- mented. There are “lace” formations containing var- ious intermetallics (Figure 4). According to color, these mixed phases can be considered as phases of iron and magnesium. An unmodified structure does not contain significant amount of shrinkage porosity. In the structure modified by agent AlSr3.5, coarse acicular to flat formations of iron and man- ganese phases occur at the grain boundaries, and there are skeletal magnesium formations, which are always bound to the iron phase and/or to the mod- ified (fibrous to acicular closer to the grain bound- aries) eutectic silicon (Figure 5). Cavities are present, usually in combination of interdendritic shrinkage and gas porosity. Figure 5: Structure modified by AlSr3.5, mag. 1 000× Figure 6: Modified by AlSr5, mag. 1 000× In the structure modified by agent AlSr5 (Fi- gure 6), acicular to rough flat formations of iron and manganese phases and skeletal magnesium forma- tions occur. There are large numbers of cavities in all samples, mostly interdendritic shrinkage porosity combined with gas. Figure 7: Modified by cast AlSr10 agent, mag. 1 000× The structure modified by cast agent AlSr10 shows rough acicular to skeletal phases of iron and manganese, and skeletal magnesium phase forma- tions, which are always bound to the iron phases (Figure 7). Finer phases of iron interfere with the eu- tectic. Interdendritic shrinkages combined with gas bubbles appear in the structure. Figure 8: Modified by wrought AlSr10 agent, mag. 1 000× In a structure modified by wrought agent AlSr10 (Figures 8, 10, 11), coarse acicular for- mations to skeletal phases of iron, manganese and skeletal magnesium phases occur. These magnesium 29 Acta Polytechnica Vol. 52 No. 4/2012 phases are always bound to the iron phases. Iron phases interfere with eutectic silicon. Coarse iron for- mations are rougher than structures modified by cast agent AlSr10. Cavities are present, usually a combi- nation of interdendritic shrinkage and gas porosity. Figure 9: Modified by pure Sr, mag. 1 000× Pure Sr affected the structure (Figure 9) in such a way that there are coarse to flat formations of iron phases which interfere with the eutectic. They are often parallel. Magnesium phases are gentle, always tied to different phases. There are also small round to teardrop-shaped formations of mixed phases. Com- bined porosity is present. 5 Discussion of results The expected result of modification — finer morphol- ogy of eutectic silicon — was obtained by all mod- ification agents, even by pure strontium, the resid- ual content of which in the sample is lower than the other modification agents (see Table 2). This lower measured amount in the cast sample can be explained by the worse dissolution conditions when strontium in pure metal form is added to the melt. The residual content of strontium in samples mod- ified by pre-alloys with aluminum (AlSr3.5, AlSr5, wrought AlSr10 and cast AlSr10) is comparable, close to an added amount of 400 ppm. Two agents (AlSr5 and wrought AlSr10) reached a higher residual stron- tium value than the added amount of 400 ppm. This phenomenon can be explained by higher local con- centration of strontium. Figures 4 to 9 show the structures of the unmod- ified sample and samples modified by various mod- ification agents based on strontium. In particular, details of intermetallic phases, which are characteris- tic for AlSi10Mg alloy, are shown. Namely there are phases of iron and magnesium. Other elements, listed in Tables 1 or 2, are dissolved in solid solution or they are contained in complex intermetallic phases. For example, manganese is usually a part of the inter- metallic phases of iron (characteristic skeleton phases also called Chinese script, e.g. in Figure 2). Figure 10: Hydrogen bubbles on the fracture area, both samples are modified by the wrought AlSr10 agent Figure 11: Dendritic arms and interdendritic shrink- age on the fracture area, both samples are modified by the wrought AlSr10 agent Unmodified structures, especially characteristic intermetallic phases (Figure 4), have a different mor- phology from modified structures. The most signif- icant difference can be observed in the morphology of magnesium phase Mg2Si (black color particles in Figure 4, or skeletal shapes in other pictures). The sample obtained by pure strontium modifying has the morphology of the Mg2Si phases closest to the un- modified structures. This similarity is also related to the residual strontium content in this sample (Tab- le 2). The iron phases also have a different morphol- 30 Acta Polytechnica Vol. 52 No. 4/2012 ogy in the unmodified sample and in the structure ob- tained by modification, where these phases are more skeletal or flat, and not so coarse. The only excep- tion is again the structure modified by pure stron- tium, which is similar to the unmodified structure, and also contains “lace” or teardrop-shaped forma- tions of mixed phases. The specific phenomenon of non-binary alloys can be observed, e.g. the AlSi10Mg alloy that the intermetallic phases interfere with each other and with eutectic silicon on the eutectic grain boundaries. Magnesium phase Mg2Si in particular, is always bound to phases of iron. Structural defects, especially cavities, were also observed in the obtained structures. It can be stated that the unmodified structure contains less porosity than the modified structure. Even the structure mod- ified by pure strontium contains more cavities of com- bined porosity. 6 Conclusions The following conclusions can be drawn based on the presented experiments: • All structures (apart from the unmodified struc- tures) were modified, and the morphology of eu- tectic silicon was changed from coarse to finer acicular or fibrous eutectic silicon. Modifica- tion was achieved by all the modification agents based on strontium that were used. • It was observed that the structure of a non- binary alloy such as AlSi10Mg can also be influ- enced by strontium (in addition to the modifi- cation effect): the coarse acicular morphology of iron based intermetallic phases changes to a flat- ter shape or even to a skeletal shape when stron- tium is added. This finding confirms and com- plements findings of other authors (e.g. [2,4–6]). • It was found that in the non-binary system Al– Si–Mg intermetallic phases of magnesium are also affected by the addition of strontium: espe- cially phase Mg2Si changes significantly in mor- phology from an unmodified structure to a mod- ified structure. The change can be described as a transformation from a fragmented phase to skeletal formations. • It was confirmed that the addition of stron- tium influences structural defects such as cav- ities. Modified structures show a greater degree of porosity, which can generally be referred to as combined porosity (gas + shrinkage). • It was confirmed that various modification agents based on strontium, with various amounts of strontium in the pre-alloy, behave differently with different effects. The effect on the mor- phology and the mechanical properties of eutec- tic silicon has been published e.g. in [8–10]. The effect on the morphology of intermetallic phases is described above. For an exact description of the influence for each individual pre-alloy, it will be necessary to make further observations with a qualitative and quantitative evaluation of the morphology of the intermetallic phases. • There are significant differences between unmod- ified structures and modified structures (irre- spective of the modification agent): in addi- tion to the change in eutectic silicon morphol- ogy, changes in the morphology of intermetallic phases, e.g. phases based on iron and magne- sium, are observed (see above). • The changes in the morphology of the inter- metallic phases influence the mechanical prop- erties of the alloy. The work has shown that strontium affects the morphology of intermetal- lic phase Mg2Si. This phase can influence not only tensile strength or ductility, but also the process of heat treatment, mainly hardening of Al alloys, which comprises solution annealing and aging. It can be assumed that if the hard- ening phase Mg2Si has a suitable and control- lable morphology, with uniform distribution in the volume of the casting, the annealing could be shortened or the effect of heat treatment could be greater. Further studies are needed, and more experiments need to be performed, to verify this assumption. Acknowledgement The work presented in this paper was supported by project SGS OHK2-038/10. References [1] Gruzleski, J. E., Closset, B. E.: The Treat- ment of Liquid Aluminium — Silicon Alloys. Des Plaines: American Foundrymen’s Society, Inc., 1999. 256 pp. [2] Cho, Y. H., et al.: Effect of Strontium and Phos- phorus on Eutectic Al–Si Nucleation and Forma- tion of β-Al5FeSi in Hypoeutectic Al–Si Foundry Alloys. Metallurgical and Materials Transac- tions. 2008, Vol. 39, No. 10, p. 2 435–2 448. http://www.springerlink.com/content/ 6883p01714hp2774/ DOI: 10.1007/s11661-008-9580-8. 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