Abstract

1. Introduction

Bulk metallic glasses, BMG, and nanocrystalline alloys represent new possibilities for microstructural engineering of materials. One way to measure the glass forming ability (GFA) is the critical cooling rate to avoid the ‘‘nose’’ of the time-temperature-transition (TTT) curve for a specific alloy. The nucleation and growth mechanism determines the shape and position of the TTT curve in the temperature- time space. In most of cases, by avoiding the nose, external infuencens prevent inherent homogeneous crystallization ¹1 Drehman AJ, Greer AL. Kinetics of crystal nucleation and growth in Pd40Ni40P20 glass. Acta Metallurgica. 1984;32(3):323-332.

2 Nishiyama N, Inoue A. Supercooling investigation and critical cooling rate for glass formation in Pd-Cu-Ni-P alloy. Acta Materialia. 1999;47(5):1487-1495.

3 Shen TD, Schwarz RB. Bulk ferromagnetic glasses prepared by flux melting and water quenching. Applied Physics Letters. 1999;75(1):49-51.^-44 Schroers J, Yue W, Johnson WL. Heterogeneous influences on the crystallization of Pd43Ni10Cu27P20. Philosophical Magazine A. 2002;82(6):1207-1217.. If a critical cooling rate is achieved for a stated dimension ⁵5 Suryanarayana C, Koch CC. Nanocrystalline materials - Current research and future directions. Hyperfine Interactions. 2000;130(1):5-44., compositions that possess high glass-forming ability can be produced as amorphous solids by rapid solidification processes, such as suction-casting⁶6 Nishiyama N, Amiya K, Inoue A. Novel applications of bulk metallic glass for industrial products. Journal of Non-Crystalline Solids. 2007;353(32-40):3615-3621..

Systems that possess high GFA usually follow the conventional proposed criteria involving relations between crystallization, melting and glass transition temperatures, along with a negative heat of mixing, topological factors, critical cooling rate and critical dimension ⁷7 Suryanarayana C, Inoue A, eds. Bulk Metallic Glasses. Boca Raton: CRC Press; 2011.. Eutectic Copper-Zirconium based alloys exhibit high GFA, the rapid solidification of these alloys can lead to the formation of BMG’s ⁸8 Tang MB, Zhao DQ, Pan MX, Wang WH. Binary Cu-Zr Bulk Metallic Glasses. Chinese Physics Letters. 2004;21(5):901-903.

9 Xu D, Lohwongwatana B, Duan G, Johnson WL, Garland C. Bulk metallic glass formation in binary Cu-rich alloy series - Cu100-x Zrx (x= 34, 36, 38.2, 40 at.%) and mechanical properties of bulk Cu64Zr36 glass. Acta Materialia. 2004;52(9):2621-2624.^-1010 Zhang Q, Zhang W, Inoue A. New Cu-Zr-based bulk metallic glasses with large diameters of up to 1.5 cm. Scripta Materialia. 2006;55(8):711-713.. Near eutectic Cu-Zr based systems have been extensively studied due to their interesting properties, such as high corrosion resistance ¹¹11 Zhang W, Zhang Q, Qin C, Inoue A. Synthesis and properties of Cu-Zr-Ag-Al glassy alloys with high glass-forming ability. Materials Science and Engineering: B. 2008;148(1-3):92-96.^,1212 Inoue A. Stabilization of metallic supercooled liquid and bulk amorphous alloys. Acta Materialia. 2000;48(1):279-306. and good mechanical strength ¹³13 Yu P, Bai HY, Wang WH. Superior glass-forming ability of CuZr alloys from minor additions. Journal of Materials Research. 2006;21(7):1674-1679.^,1414 Inoue A, Zhang W. Formation, Thermal Stability and Mechanical Properties of Cu-Zr-Al Bulk Glassy Alloys. Materials Transactions. 2002;43(11):2921-2925.. These systems are thus useful as engineering materials. Zr-(Cu-Ag)-Al bulk metallic glasses can be produced by suction-casting in copper molds with large diameters, the Zr₄₈Cu_38.5Ag_5.5Al₈ composition achieving 20 mm¹⁵15 Jiang QK, Wang XD, Nie XP, Zhang GQ, Ma H, Fecht HJ, et al. Zr-(Cu,Ag)-Al bulk metallic glasses. Acta Materialia. 2008;56(8):1785-1796.and the Cu₄₃Zr₄₃Al₇Ag₇, 8mm ¹⁶16 Lee SW, Huh MY, Fleury E, Lee JC. Crystallization-induced plasticity of Cu-Zr containing bulk amorphous alloys. Acta Materialia. 2006;54(2):349-355..

However, contrary to crystals, BMGs suffer from a lack of crystalline defects such as dislocations and commonly do not present ductility in uniaxial mechanical tests ¹⁷17 Schuh C, Hufnagel TC, Ramamurty U. Mechanical behavior of amorphous alloys. Acta Materialia. 2007;55(12):4067-4109.. In such case, BMGs lead to shear bands formation, localizing the plastic deformation ¹⁸18 Zhang ZF, Eckert J, Schultz L. Difference in compressive and tensile fracture mechanisms of Zr59Cu20Al10Ni8Ti3 bulk metallic glass. Acta Materialia. 2003;51(4):1167-1179.. This restricts the overall plasticity of BMGs in most cases to less than 1% and hampers the use of BMGs as a structural material in several possible utilization. For the sake of overcoming the problem of the poor plasticity of BMG at room temperature and allow the development of structural materials, attempts have been concentrated on the production of BMG composites. A diversity of composite materials have been produced either by adding a crystalline phase into the liquefied BMG ¹⁹19 Choi-Yim H, Johnson W. Bulk metallic glass matrix composites. Applied Physics Letters. 1997;71(26):3808. or by in situ precipitation of crystalline phases throughout partial crystallization ²⁰20 Hays CC, Kim CP, Johnson WL. Microstructure Controlled Shear Band Pattern Formation and Enhanced Plasticity of Bulk Metallic Glasses Containing in situ Formed Ductile Phase Dendrite Dispersions. Physical Review Letters. 2000;84(13):2901.^,2121 Kühn U, Eckert J, Mattern N, Schultz L. ZrNbCuNiAl bulk metallic glass matrix composites containing dendritic bcc phase precipitates. Applied Physics Letters. 2002;80(14):2478.. Such a methodology allows enhanced plasticity in BMG composites by generating multiple shear bands, which will interact with each other, thus limiting a single shear band from crossing within the material.

A simple way of producing such a composite is by not reaching the critical cooling rate. The product of solidification may then present a second phase embedded in the amorphous alloy, improving the yield²²22 Inoue A, Fan C, Saida J, Zhang T. High-strength Zr-based bulk amorphous alloys containing nanocrystalline and nanoquasicrystalline particles. Science and Technology of Advanced Materials. 2000;1(2):73-86. and flexural strength ²³23 Inoue A. Bulk amorphous and nanocrystalline alloys with high functional properties. Materials Science and Engineering: A. 2001;304-306:1-10., and ductility ²⁴24 Fan C, Takeuchi A, Inoue A. Preparation and Mechanical Properties of Zr-based Bulk Nanocrystalline Alloys Containing Compound and Amorphous Phases. Materials Transactions, JIM. 1999;40(1):42-51..

Sn was chosen as substitutional element due to the improved corrosion resistance in Zirconium based alloys when small amount of this element is added ²⁵25 Wei J, Frankel P, Polatidis E, Blat M, Ambard A, Comstock RJ, et al. The effect of Sn on autoclave corrosion performance and corrosion mechanisms in Zr-Sn-Nb alloys. Acta Materialia. 2013;61(11):4200-4214. and its low cost in comparison to Ag. Furthermore, the atomic radius and electronegativity of Ag and Sn are very similar, thus allowing keeping the good GFA of the alloy.

This work aims to synthesize by a rapid solidification method Cu₄₂Zr₄₂Al₈Ag₈ and Cu₄₂Zr₄₂Al₈Ag₄Sn₄ alloys, infer about the microstructure refinement and corrosion resistance effects promoted by Sn addition. The rapidly solidified alloys were produced by the suction-casting method and characterized by X-ray diffraction (XRD) along with crystallite size estimation by Scherrer equation, scanning electron microscopy (SEM) and transmission electron microscopy (TEM) techniques. Polarization curves were also obtained for corrosion resistance inference.

2. Experimental

An arc-melter Edmund Bühler GmbH furnace, with 5mm diameter copper mold, was used to produce suction-casted samples of Cu₄₂Zr₄₂Al₈Ag₈ and of the proposed composition Cu₄₂Zr₄₂Al₈Ag₄Sn₄. To crystallize the alloys during suction casting the water flow in the refrigeration system was reduced, also reducing the exchanged heat. Melting processes were performed under Argon atmosphere. To prepare these alloys Cu powder (99.99 % purity), Zr nuclear quality 99.9% purity, Al 99.99% purity, Ag 99.99% purity and Sn 99.9% purity were used. To solve the problem of Sn evaporation, Zr was positioned above Sn and these elements were previously molten together, in order to form the α-Zr and Zr₄Sn phases in equilibrium, with the melting temperature of approximately 1000°C ²⁶26 Subasic N. Thermodynamic evaluation of Sn-Zr phase diagram. Calphad. 1998;22(2):157-165.. After this step, this material was molten along with other elements.

XRD measurements were performed in G8-Discover Bruker equipment with Cu-Kα radiation, λ =1.5418 Å. Present phases were identified by comparison with the XRD patterns simulated by Powder Cell software, based on crystallographic data obtained from literature ²⁷27 Pearson WB, Villars P, Calvert LD. Pearson's Handbook of Crystallographic Data for Intermetallic Phases. Materials Park: American Society for Metals; 1985.^,2828 Liu Y, Blandin JJ, Suery M, Kapelski G. Effect of cooling rate on the microstructure and microhardness of the CuZrAgAl alloy. Materials Characterization. 2012;70:8-13.^,2929 Louzguine-Luzgin DV, Xie G, Zhang W, Inoue A. Influence of Al and Ag on the Devitrification Behavior of a Cu-Zr Glassy Alloy. Materials Transactions. 2007;48(8):2128-2132.. The Scherrer equation was used for crystallite size estimation from the XRD patterns, along with Gaussian fittings. The chosen shape factor was k = 0.9. The uncertainties were calculated using errors related to the centers of peaks and the widths. SEM images in back-scattered electrons mode were acquired with a Jeol JSM 6460LV. TEM images of the Cu₄₂Zr₄₂Al₈Ag₄Sn₄ suction-casted sample were acquired with FEI TECNAI G2 F20 microscope. The potentiodynamic polarization curves were performed in H₂SO₄ 1M solution under open air at room temperature and conducted in a three-electrode cell using a platinum counter electrode and a Hg/HgCl₂ reference electrode. These curves were measured at a rate of 600 mV/h after open-circuit immersion for about 30 min when the open-circuit potential became almost steady. The minimum and maximum applied potential were -2V and 2V.

3. Results and Discussions

Figure 1 shows the Cu₄₂Zr₄₂Al₈Ag₄Sn₄ suction-casted sample. Figures 2 and 3 show the diffraction patterns for the Cu₄₂Zr₄₂Al₈Ag₈ and the Cu₄₂Zr₄₂Al₈Ag₄Sn₄ samples, under the two studied conditions. Cu₁₀Zr₇ was markedly the most present phase. AlCu₂Zr and CuZr₂ peaks were also identified in all four samples. CuZr₂ and Cu₁₀Zr₇ are present in the Cu-Zr binary diagram ³⁰30 Zeng KJ, Hämäläinen M, Lukas HL. A new thermodynamic description of the Cu-Zr system. Journal of Phase Equilibria. 1994;15(6):577-586., and these phases along with of AlCu₂Zr are reported in the literature after copper mold casting of Cu₄₀Zr₄₄Al₈Ag₈²⁸28 Liu Y, Blandin JJ, Suery M, Kapelski G. Effect of cooling rate on the microstructure and microhardness of the CuZrAgAl alloy. Materials Characterization. 2012;70:8-13.. The red arrows in Figures 2 and 3 point to the analyzed peaks, used to generate the full width at half maximum (FWHM) and crystallite size data in Table 1. The suction-casting process led to remarkably higher FWHM and smaller crystallite sizes for all analyzed peaks in both compositions. The rapid solidification process promoted great microstructure refinement instead of leading to the formation of amorphous alloys. It can also be noted for AlCu₂Zr, CuZr₂ and Cu₁₀Zr₇ analyzed peaks, that the rapid cooling promoted similar crystallite sizes for both compositions considering the uncertainties. The addition of Sn in Cu-Zr-Al-Ag system did not lead to a significant difference in microstructure refinement obtained by the performed suction-casting.

The back-scattered electrons SEM image of the Cu₄₂Zr₄₂Al₈Ag₈ arc-melted sample (Figure 4.a) presents two main types of precipitated morphologies: “drop-like” and “cross”, dispersed in the matrix. It is noteworthy that the “cross” morphology resembles dendritic structures. After the suction-casting process, the scanning electron microscopy image (Figure 4.b) shows more refined “cross” structures, with the “drop-like” structure not exhibiting a substantial difference. A study of the microstructure of Cu₄₀Zr₄₄Al₈Ag₈ rapidly solidified in copper mold ²⁸28 Liu Y, Blandin JJ, Suery M, Kapelski G. Effect of cooling rate on the microstructure and microhardness of the CuZrAgAl alloy. Materials Characterization. 2012;70:8-13. reported the presence of a “skeletal phase” with an approximate stoichiometry of CuZr₂, which resembles the observed “cross” structure. The existence of a “blocky phase” is also reported with a stoichiometry of approximately Cu₁₀Zr₇, resembling the “drop-like” structures observed in this study. The points selected for EDS analysis of Cu₄₂Zr₄₂Al₈Ag₈ suction-casted sample are shown in Figure 5.a and the atomic percent results are in Table 2. Point 1 is marked inside the “drop-like” precipitate and point 2 in the matrix. The results of the EDS analysis allow for inferring that all elements are present in both regions, and point 1 contains less Cu and Ag. These regions could not be assigned to specific phases. The presence of Oxygen in point 1 is probably due to an oxidation process.

White oriented columns, cross structures, and other structures without defined shape are dispersed inside the matrix, in the microstructure of the Cu₄₂Zr₄₂Al₈Ag₄Sn₄ arc-melted sample (Figure 4.c). After rapid solidification, the formation of white oriented columnar structures is suppressed and the white phase is quenched into smaller structures (Figure 4.d). To investigate the composition of the different regions of the Cu₄₂Zr₄₂Al₈Ag₄Sn₄ suction-casted sample, EDS analysis was performed. The selected points for EDS analyses and results are shown in figure 5.b and Table 2. Point 3 is marked on the white phase and presents Sn , Zr, Cu, and Al in its composition. Point 4 is marked inside the matrix and presents Ag, Zr, Cu and Al in its composition. Therefore, the white phase contains Sn and not Ag, while in the matrix region this relation is the opposite. The relevant atomic percent of Sn exhibited on point 3 suggests that the white columnar phases contain this element and these structures may contain the AlSn₃Zr₅ phase. Figures 4.e and 4.f show the TEM image of Cu₄₂Zr₄₂Al₈Ag₄Sn₄ suction-casted sample and the SAEDP. The presence of small crystalline precipitates in grain boundaries, pointed by red arrows, is remarkable. Furthermore, in SAEDP, small dispersive points in diffusive halo can be noted. This behavior can be related to small crystalline structures ³¹31 Biju V, Sugathan N, Vrinda V, Salini SL. Estimation of lattice strain in nanocrystalline silver from X-ray diffraction line broadening. Journal of Materials Science. 2008;43(4):1175-1179.^,3232 Medeiros BB, Kiminani CS, Botta WJ, Bolfarini C, Jorge Junior AM. Hot Consolidation of Partially Amorphous Cu-Ti Based Alloy: a Comparison Between Hot Extrusion and Hot Compaction by Sintering. Materials Research. 2015;18(3):448-452..

Figure 6 presents the polarization curves and the Table 3 displays the passivation current (I) for all analyzed samples. For Cu₄₂Zr₄₂Al₈Ag₈ composition, the peak at the beginning of anodic polarization and passivation current became lower after the suction-casting. This behavior suggests better corrosion resistance after microstructure refinement ¹¹11 Zhang W, Zhang Q, Qin C, Inoue A. Synthesis and properties of Cu-Zr-Ag-Al glassy alloys with high glass-forming ability. Materials Science and Engineering: B. 2008;148(1-3):92-96., as expected. Considering the Cu₄₂Zr₄₂Al₈Ag₄Sn₄ composition, although the suction-casted sample presented a lower peak at beginning of anodic polarization, the passivation current was higher. This suggests that the microstructure refinement promoted by rapid solidification process in the proposed composition did not lead to an increase in corrosion resistance. The passivation currents for arc-melted and suction-casted samples increased with Sn addition, this allows inferring that the Sn addition decreased the corrosion resistance of arc-melted and suction-casted samples.

4. Conclusions

The Cu₄₂Zr₄₂Al₈Ag₈ and the novel Cu₄₂Zr₄₂Al₈Ag₄Sn₄ suction-casted samples presented great microstructural refinement, as shown by XRD, SEM and crystallite size estimation. After rapid solidification, the crystallite size estimation of the common peaks resulted in similar values. The rapid solidification of the proposed composition led to the formation of small crystalline precipitates the grain boundaries, as noted in TEM images. The addition of Sn led to high passivation currents. These results allow for inferring that Sn addition did not clearly affect microstructural refinement, however, it decreased the corrosion resistance.

5. Acknowledgments

We thank FAPERJ, CNPq and CAPES, for financial support and also thank the LCE laboratory of UFSCAR for performing the TEM analysis.

6. References

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