Abstract

1. Introduction

Over the last few years, extensive research has been carried out to improve the properties of metallic glasses, such as the physical, chemical, magnetic and mechanical properties. The corrosion behavior of Bulk Metallic Glasses (BMG) is important when these materials are used in aggressive and hostile environments (high temperatures, oxidizing atmospheres and corrosive media)¹1 Suryanarayana C, Inoue A. Iron-based bulk metallic glasses. International Materials Reviews. 2013;58(3):131-166.. In Fe-based alloys, adding some elements such as Cr is known to improve the corrosion resistance of theses alloys, however it also reduces the Glass Forming Ability (GFA)²2 Archer MD, Corke CC, Harji BH. The electrochemical properties of metallic glasses. Electrochimica Acta. 1987;32(1):13-26.. The percentage of Cr in the glass former alloy could be lower than that of stainless steel as only 2% is sufficient to be resistant to pitting and crevice corrosion. In 1 N HCl solutions, the Fe_67.6C_7.1Si_3.3B_5.5P_8.7Cr_2.3Mo_2.5Al_2.0Co_1.0 alloy containing 2.3 at% Cr showed a corrosion resistance similar to the 304 stainless steel that contains high Cr (19 at% Cr) and Ni (9 at% Ni) contents³3 Wang SL, Li HX, Zhang HF, Yi S. Effects of Cr contents in Fe-based bulk metallic glasses on the glass forming ability and the corrosion resistance. Materials Chemistry and Physics. 2009;113(2-3):878-883.. This behavior indicates a promising replacement of stainless steel alloys by glassy alloys in various applications.

Despite the fact that Cr reduces the GFA of the alloy, it has been reported in the literature that a Fe-based BMG can be obtained containing up to 15 at.% Cr and 16 at.% Cr⁴4 Pang SJ, Zhang T, Asami K, Inoue A. Bulk glassy Fe-Cr-Mo-C-B alloys with high corrosion resistance. Corrosion Science. 2002;44(8):1847-1856.^,55 Pang SJ, Zhang T, Asami K, Inoue A. Synthesis of Fe-Cr-Mo-C-B-P bulk metallic glasses with high corrosion resistance. Acta Materialia. 2002;50(3):489-497.^,66 Jayaraj J, Kim KB, Ahn HS, Fleury E. Corrosion mechanism of N-containing Fe-Cr-Mo-Y-C-B bulk amorphous alloys in highly concentrated HCl solution. Materials Science and Engineering: A. 2007;449-451:517-520.^,77 Bakare MS, Voisey KT, Chokethawai K, McCartney DG. Corrosion behaviour of crystalline and amorphous forms of the glass forming alloy Fe43Cr16Mo16C15B10. Journal of Alloys and Compounds. 2012;527:210-218.^,88 Ni HS, Liu XH, Chang XC, Hou WL, Liu W, Wang JQ. High performance amorphous steel coating prepared by HVOF thermal spraying. Journal of Alloys and Compounds. 2009;467(1-2):163-167. and the corrosion resistance can be significantly improved due to this higher amount of Cr.

Besides Cr, molybdenum and niobium additions have also been extensively studied because both are also effective in promoting anodic passivation (similar to what happens to Cr), even in acidic chloride solution²2 Archer MD, Corke CC, Harji BH. The electrochemical properties of metallic glasses. Electrochimica Acta. 1987;32(1):13-26.. Kiminami et al. reported that a small quantity of Nb and/or Mo, lower than the minimum concentration generally used in commercial stainless steel (0.6 wt.%), is sufficient to increase the general corrosion resistance, as well as the pitting corrosion resistance of glassy Fe-Cr-based alloys⁹9 Kiminami CS, Souza CAC, Bonavina LF, de Andrade Lima LRP, Suriñach S, Baró MD, et al. Partial crystallization and corrosion resistance of amorphous Fe-Cr-M-B (M = Mo, Nb) alloys. Journal of Non-Crystalline Solids. 2010;356(44-49):2651-2657.. It has been shown that Mo is more effective in enhancing corrosion resistance than the Nb in 4.0 M HCl solution, and the alloy containing both Nb and Mo presented more overall corrosion resistance than the alloy containing only one of these elements¹⁰10 Souza CAC, Bolfarini C, Botta Jr. WJ, de Andrade Lima LRP, Falcão de Oliveira M, Kiminami CS. Corrosion resistance and glass forming ability of Fe47Co7Cr15M9Si5B15Y2 (M=Mo, Nb) amorphous alloys. Materials Research. 2013;16(6):1294-1298.. Furthermore, the presence of these two elements favors the increase in the GFA of the alloy.

Regarding the design and selection of compositions in Fe-based BMG with additions of Cr, Nb and B elements, Cheney and Vecchio¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235. reported a modeling criterion that simultaneously analyzes the thermodynamics and kinetics of the vitrification behavior in a potential glass-forming alloy. The authors used a liquidus model (parameter α) to determine and rank the presence of deep eutectics. Moreover, this model was cross-checked with an elastic strain model (parameter ε) in a pseudo-ternary phase diagram. The authors analyzed 19 samples of this Fe-Cr-Nb-B system, and both theoretical and experimental results showed that one of the optimal compositions is the Fe₆₀Cr₈Nb₈B₂₄. However, the authors did not consider the compositions with a high percentage of both Cr and Nb, which can offer better resistance to corrosion.

To analyze the liquidus temperature calculations, a dimensionless parameter, α, is used to quantify the depth of the eutectic, where a high value of alpha means a potentially good glass-forming alloy¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235.^,1212 Marcus M, Turnbull D. On the correlation between glass-forming tendency and liquidus temperature in metallic alloys. Materials Science and Engineering. 1976;23(2-3):211-214.. The parameter α is described by Eq. (1), where x_i is the atomic percent of the ith element and T_l is the liquid temperature of the alloy.

The parameter ε, which calculates the elastic strain energy that must be stored in an emerging crystalline nucleus, is described in ref. 5. This elastic strain criterion states that the mean local strain must exceed 0.054 in order to destabilize the crystal lattice formation and encourage amorphization¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235.^,1212 Marcus M, Turnbull D. On the correlation between glass-forming tendency and liquidus temperature in metallic alloys. Materials Science and Engineering. 1976;23(2-3):211-214..

Based on these modeling criteria and on the Fe₆₀Cr₈Nb₈B₂₄ alloy reported by Cheney and Vecchio¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235. as a good GFA, for this study the Fe_68-xCr_xNb₈B₂₄ (x=10,12) compositions were considered as candidates to be new compositions of BMG with higher corrosion resistance due to the higher Cr content. It can be observed that these compositions have the desirable conditions established by Cheney and Vecchio¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235., i.e., high value of alpha, ε > 0.054 and a chemical short range order parameter (CSRO)< (-0.04). A Nb concentration above 8 at.% was not used because it reduces the GFA¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235.. Concerning the B element, a concentration above 24 at.% slightly increases the GFA¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235., thus it was maintained at this concentration as the Fe₆₀Cr₈Nb₈B₂₄ alloy. Thus, in order to increase the Cr, it was decided to decrease the Fe content and not the B one because it favors the GFA⁴4 Pang SJ, Zhang T, Asami K, Inoue A. Bulk glassy Fe-Cr-Mo-C-B alloys with high corrosion resistance. Corrosion Science. 2002;44(8):1847-1856..

This paper analyzes the effect of the increase in the Cr content on the structure and thermal stability of Fe_68-xCr_xNb₈B₂₄ (x=10,12) alloys. For the sake of comparison, the Fe₆₀Cr₈Nb₈B₂₄ alloy reported by Cheney and Vecchio was also evaluated in this work.

2. Experimental Procedures

The Fe_68-xCr_xNb₈B₂₄ (x=8,10,12) alloy ingots were produced by arc-melting the pure elements under an argon atmosphere. Rapidly solidified ribbons, approximately 1.4 mm wide and 45 µm thick were produced from the ingots, using a single-roller melt spinner at a tangential wheel speed of 40 m/s in an argon atmosphere. Bulk wedge-shaped samples with 0.5 µm up to 5 mm thick and 40 mm long were produced by the suction casting method in a copper mold. The samples were structurally characterized by X-ray diffraction (XRD) with Cu-Kα radiation and scanning electron microscopy (SEM). The liquidus temperature (T_l) of the alloys and the thermal stability of the glassy samples were evaluated using differential scanning calorimetry (DSC) and differential thermal analysis (DTA) at a heating rate of 0.67 K/s under a flowing Ar atmosphere.

3. Results and Discussion

Figure 1 presents the thermograms of the as-quenched ribbon. The arrows in Figure 1a indicate the glass transition temperature (T_g) and the crystallization temperature (T_x), and the arrows in Figure 1b indicate the liquidus temperature (T_l). These measured thermal parameters (T_g, T_x and T_l), and the calculated ΔT_x (supercooled liquid region, ΔT_x = T_x-T_g), γ parameter (T_x/(T_g+T_l))¹³13 Lu ZP, Liu CT. A new glass-forming ability criterion for bulk metallic glasses. Acta Materialia. 2002;50(13):3501-3512. and Z_C (critical thickness of the composition calculated using the relationship Z_c=2.80e(−7) exp (41.70γ))¹³13 Lu ZP, Liu CT. A new glass-forming ability criterion for bulk metallic glasses. Acta Materialia. 2002;50(13):3501-3512. are summarized in Table 1. According to Lu and Liu¹³13 Lu ZP, Liu CT. A new glass-forming ability criterion for bulk metallic glasses. Acta Materialia. 2002;50(13):3501-3512., γ values for BMGs vary from 0.350 to 0.500, therefore it would be possible to obtain a BMG with these alloy compositions, and it is theoretically possible to obtain an amorphous structure up to 3.5 mm for the Fe₅₈Cr₁₀Nb₈B₂₄ alloy and up to 1.6 mm for the Fe₅₆Cr₁₂Nb₈B₂₄ alloy. The Fe₆₀Cr₈Nb₈B₂₄ alloy obtained a higher ΔTx (=60 K) and Z_C (=4.35 mm) value than that reported by Cheney and Vecchio (ΔT_x=55 K and Zc=3.44 mm)¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235..

Figure 2 shows the X-ray diffraction patterns of the as-quenched ribbons. It can be observed that all the alloys have a halo without any peaks, which is a characteristic of an amorphous structure, i.e. indicating that there was a formation of an amorphous structure. Despite these XRD results for the Fe₅₆Cr₁₂Nb₈B₂₄ alloy, Figure 3b shows the SEM micrograph in which the crystalline phases can be observed in the cross-section of the ribbon at a quantity that the XRD certainly did not detect. The SEM micrograph of the melt-spun Fe₅₈Cr₁₀Nb₈B₂₄ ribbon showed no evidence of crystalline phases, as shown in Figure 3a. This result, which showed higher GFA of Fe₅₈Cr₁₀Nb₈B₂₄ compared with Fe₅₆Cr₁₂Nb₈B_24, was predicted by the γ parameter (0.39 and 0.37 respectively) and by the critical thickness Z_C (3.56 and 1.63 mm respectively), as presented in Table 1.

The low tendency of the GFA of the Fe₅₆Cr₁₂Nb₈B₂₄ alloy is attributed to the high Cr content. Nevertheless, in the literature, cases can be found reporting BMG for alloys with a high Cr content, such as in the Fe₄₃Cr₁₆Mo₁₆C₁₀B₅P₁₀ (at%)⁵5 Pang SJ, Zhang T, Asami K, Inoue A. Synthesis of Fe-Cr-Mo-C-B-P bulk metallic glasses with high corrosion resistance. Acta Materialia. 2002;50(3):489-497. and Fe₄₃Cr₁₆Mo₁₆C₁₅B₁₀ (at%)⁷7 Bakare MS, Voisey KT, Chokethawai K, McCartney DG. Corrosion behaviour of crystalline and amorphous forms of the glass forming alloy Fe43Cr16Mo16C15B10. Journal of Alloys and Compounds. 2012;527:210-218. alloys, and this behaviour has been attributed to the high Mo content in these alloys, which is favorable in terms of increasing the GFA¹⁴14 Takeuchi A, Inoue A. Mixing enthalpy of liquid phase calculated by miedema's scheme and approximated with sub-regular solution model for assessing forming ability of amorphous and glassy alloys. Intermetallics. 2010;18(9):1779-1789.. Moreover, in these alloys, the partial substitution of B by C and/or P also helps to increase the GFA⁵5 Pang SJ, Zhang T, Asami K, Inoue A. Synthesis of Fe-Cr-Mo-C-B-P bulk metallic glasses with high corrosion resistance. Acta Materialia. 2002;50(3):489-497..

The Fe₅₈Cr₁₀Nb₈B₂₄ alloy bulk sample, which has a thickness as high as 45 mm processed by the suction casting method, was analyzed by SEM. Figure 4a shows the SEM micrographs of a region (thickness around 1.0 mm) where some crystallized phases in the wedge-section of the Fe₅₈Cr₁₀Nb₈B₂₄ alloy can be observed. In this region, the microstructure consists of a few crystalline phases embedded in an amorphous matrix (featureless region). Figure 5 shows the X-ray diffraction patterns of three different regions of this sample (with 0.6 mm, 1.0 mm and 3 mm thicknesses). The diffraction pattern shows a fully glassy structure of 0.6 mm thickness and this is in agreement with Figure 4, where it can be observed that the early crystallized phases appear in the range of 0.6 to 1.0 mm. Combining the SEM and XRD analysis, the experimental critical thickness, Z_C, of around 0.6 mm for Fe₅₈Cr₁₀Nb₈B₂₄ alloy is lower than that theoretically predicted (3.56 mm as shown in Table 1).

For the Fe₆₀Cr₈Nb₈B₂₄ alloy, the same procedure of characterization of the bulk sample was performed by XRD and SEM. Combining the SEM and XRD analysis, the experimental critical thickness (Z_C) achieved was approximately 1 mm for this alloy, which is lower than that theoretically predicted in this paper (4.35 mm as shown in Table 1) and also lower than that theoretically predicted by Cheney and Vecchio (3.4 mm)¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235..

Studies to determine the experimental critical thickness by using the bulk wedge-shaped casting method, as seen in this paper, is widely used in this field of research. Nevertheless, the reproducibility of this method is a challenge, as reported by Sanders et al.¹⁵15 Sanders WS, Warner JS, Miracle DB. Stability of Al-rich glasses in the Al-La-Ni system. Intermetallics. 2006;14(3):348-351., where the experimental critical thickness for Al₈₆La₅Ni₉ alloy reported was 685±95 µm after processing three samples. In view of this, the critical thicknesses for the Fe-Cr-Nb-B presented here might be higher, by improving the experimental procedures such as optimizing the alloy preparation and processing parameters. Therefore, the three compositions considered in this paper were ranked and this is in agreement with that predicted theoretically: the GFA decreases with increasing Cr content.

4. Conclusions

Rapidly solidified glassy ribbons were processed, and based on their thermal characteristics, the theoretical critical thickness (Z_C) was obtained. The estimated Z_C of the two new compositions with a higher Cr content were lower than those estimated by Cheney and Vecchio¹¹11 Cheney J, Vecchio K. Development of quaternary Fe-based bulk metallic glasses. Materials Science and Engineering A. 2008;492(1-2):230-235.. Furthermore, the critical thickness (Zc) was obtained experimentally using the wedge-shaped casting method, however this value of Zc was much lower than the one estimated theoretically. Furthermore, the GFA ranking among the three compositions studied here was established experimentally and is in agreement with that predicted theoretically, which foresaw that GFA decreases when the Cr percentage is increased. The glass forming ability of Fe₅₈Cr₁₀Nb₈B₂₄, with a fully amorphous bulk sample which was around 0.6 mm thick according to the DRX analysis (estimated theoretically as high as 3.56 mm), offers a good prospect for a new Fe-based glass former alloy with improved corrosion resistance compared with the already reported Fe₆₀Cr₈Nb₈B₂₄ alloy.

5. Acknowledgements

The authors would like to thank FAPESP (ProjetoTemático n. 2013/05987-8) and CNPq for the financial support. The authors would also like to thank Mr. Filipe Belandrino Swerts and Mr. Victor Felipe Moscoso Linares for their help in processing the samples.

6. References

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