1. Addition of RE elements

Due to the affinity of RE elements for oxygen, they can scavenge oxygen impurity and promote the formation of innocuous oxides which results in an increase of the GFA. ^{Reference Koval, Firstov and Kotko4} However, a drawback for using RE elements is that microalloying element is relatively expensive. A cheaper and sometimes more effective option, to increase the GFA, is to use mischmetal (MM), i.e., a mixture of RE elements in naturally occurring proportions. There are several types of MMs such as LaMM (lanthanum mischmetal) and CeMM (cerium mischmetal), which are named according to the most abundant element present in the mixture.

Table I lists the critical amorphous diameter (D _c) of various alloys corresponding to the Mg–Ni–La system and the same alloys when La is fully substituted by LaMM. ^{Reference González, Figueroa, Zhao, Davies, Todd and Adeva31} Among these compositions, the Mg₆₅Ni₂₀LaMM₁₅ is the one which exhibits the highest D _c. Also, it is the composition for which the critical amorphous diameter increases the most, from 0.5 to 2 mm, after the substitution of La by LaMM. The GFA parameters ΔT _x, T _rg, and γ were calculated from the measured parameters (glass transition temperature: T _g, crystallization onset temperature: T _x, solidus temperature: T _m and liquidus temperature: T _l), however, no clear correlation between D _c and either ΔT _x or T _rg was observed. Moreover, the magnitude of the γ parameter is relatively insensitive to compositional changes. These results suggest that the parameters ΔT _x, T _rg, and γ are not reliable indicators of the GFA for this set of alloys. ^{Reference González, Figueroa, Zhao, Davies, Todd and Adeva31}

TABLE I.

Critical amorphous diameter (D_c) for the Mg–Ni–La and Mg–Ni–LaMM systems. ^{Reference Pauly, Das, Bednarcik, Mattern, Kim, Kim and Eckert20}

To understand the reason for the high GFA of the Mg₆₅Ni₂₀LaMM₁₅ alloy, the ratio of Mg:Ni:REs was held constant at 65:20:15, as the original alloy. Table II shows the value of D _c for alloys with the same proportion of RE elements as in the LaMM. ^{Reference González, Figueroa, Zhao, Davies, Todd and Adeva31} The value of D _c increases with increasing content of Nd, which is consistent with the results of Lu et al. ^{Reference Lu, Bei and Liu35} These results thus confirm the important role of the Nd content in the glass forming ability. However, small addition of Ce also appears to be beneficial in increasing the D _c. This behavior cannot be explained from differences in heat of mixing the RE elements with Mg since they are very similar: Mg–La (−7 KJ/mol), Mg–Ce (−7 KJ/mol), Mg–Pr (−6 KJ/mol), and Mg–Nd (−6 KJ/mol). ^{Reference Takeuchi and Inoue36} It can neither be explained from the point of view of differences in atomic radii since they are practically the same for La (0.195 nm), Ce (0.185 nm), Pr (0.185 nm) and Nd (0.182 nm). ^{Reference Slater37} Li et al. ^{Reference Li, Pang, Ma and Zhang28} studied the influence of RE elements on the GFA of Mg₆₅Ni₂₀La_9.29Nd_5.71 alloy and observed that when La and Nd atoms were partially replaced by Ce atoms, the GFA increased due to a decrease in the Gibbs free energy of mixing. This phenomenon could also explain the beneficial effect of the Ce addition in enhancing the D _c for Mg₆₅Ni₂₀La_8.91Nd_5.45Ce_0.59 alloy. ^{Reference Zberg, Uggowitzer and Löffler32} These results suggest that when microalloying elements coexist in a proper ratio in the MM, the mixture can be useful to substitute expensive RE elements, such as La, ³⁸ to increase the GFA of metallic glasses at a relatively low cost. Similar effectiveness in changing the GFA of alloys corresponding to the Mg–Ni–La system is observed when minor Si–La, Y–Si–La and B–La elements are co-added. ^{Reference González, Figueroa and Todd39} Minor element co-addition has thus great potential for tuning the GFA of metallic glasses.

TABLE II.

Critical amorphous diameter of alloys containing 15 at% RE with the same proportion of RE elements as in the LaMM. ^{Reference Pauly, Das, Bednarcik, Mattern, Kim, Kim and Eckert20}

The main drawback for using the MM is the lack of an exact formulation, i.e., the composition depends on the location from where the ore is extracted. Differences in composition of the MM could have different effects on the GFA of the alloy and lead to the formation of crystalline phases of different natures, which in turn results in alloys with very different mechanical performances. ^{Reference Pérez, González, Garcés and Adeva40} This limitation makes it impractical to implement the use of the MM by industries. Moreover, the MM contains naturally present impurities coming from the ore that could have a negative effect on the GFA. An efficient technique to better control the final properties of BMGs at a relatively lower cost than using La is the addition of Yttrium (Y). This explains the wide use of this element in controlling the properties of BMGs. The main interest for using Y to increase the GFA generally stems from its effectiveness in scavenging oxygen. However, Wang et al. ^{Reference Wang, Liu, Yang, Liu, Dong and Lu27} reported recently that the mechanism for increasing the GFA of the Cu–Zr–Al alloy system when 2 at.% Y is added can be attributed to the formation of the local crystal-like orders at the atomic scale. In principle, one could expect that an increase in the crystal-like order should accelerate the crystallization rate of the glass-forming liquid; however, the GFA of the alloy increases. This paradox was explained based on the previous investigation of Cheng et al. ^{Reference Cheng, Ma and Sheng41} where the authors identified the co-existence in the Cu–Zr based BMG of a competition process of the crystal growth and formation of icosahedra-like orders. These icosahedra-like clusters can pin the boundaries of crystal-like clusters and limit their growth, ^{Reference Zhang, Chen, Chen and Liu26} thus resulting in an overall structural ordering that reduces the thermodynamic driving force for crystallization. This process slows down the crystallization rate and thus enhances the GFA.

2. Addition of transition elements

Microalloying with most transition metals can improve the GFA of Al-based BMGs. For example, partial substitution of Al by 0.5 at.% TM (with the exception of the late transition elements Ni and Cu) in the Al₈₈Y₇Fe₅ alloy increases the GFA. ^{Reference Bondi, Gangopadhyay, Marine, Kim, Mukhopadhyay, Goldman, Buhro and Kelton42} Among these elements, the early TM elements (Ti, V, and Cr) exhibit larger ΔT _x, from 34 to 44 °C, than the mid TM elements (Co and Fe), ΔT _x from 22 to 27 °C, which is consistent with the larger GFA of the former elements. From synchroton diffraction and EXAFS, it was concluded that the GFA increase with minor Ti addition was due to the formation of short- and medium-range orders that decrease the atomic mobility in the glass, enhancing the glass stability (i.e., increasing the nucleation barrier) and thus making the nucleation of α-Al more difficult.

In other alloy systems the superior GFA is attributed to a covalent atomic interaction. For example, it was observed in Ce–Al–Cu BMGs that addition of 0.2–3.0 at.% of Fe, Co Ni, Nb, Si, C or B increases the maximum amorphous diameter from 2 to 10 mm (Ref. Reference Zhang, Zhao, Pan, Wang and Wang43) due to the strong covalent interaction between Fe, Co, Ni, Nb, and the Al matrix. Chathoth et al. ^{Reference Chathoth, Damaschke, Embs and Samwer44} detected, for the same Ce–Al–Cu alloy system, strong variations in the relaxational dynamics while microalloying with 1 at.% Nb and the enhancement of GFA was correlated with a decrease of the self-diffusivity close to the melting temperature by about 74% and also to a temperature dependence change from Arrhenius to non-Arrhenius behavior. ^{Reference Chathoth, Damaschke, Embs and Samwer44} However, TMs can also have a negative effect on the GFA of some systems. Partial substitution of Ni by 3–5 at.% Pd decreases the GFA of the Zr₅₅Al₁₀Cu₃₀Ni_(5−x)Pd _x alloy. ^{Reference Qin, Zhang, Wang, Ding and Hu45} Addition of Pd promotes the formation of Zr–Pd and Zr–Al pairs that can form Zr–Pd and Zr–Al clusters acting as homogeneous nucleation sites for the Zr₂(Pd,Ni)-type phase and the Zr₃Al₂-type phase, respectively. This is consistent with the decrease of the supercooled liquid region ΔT _x from 82 K for Zr₅₅Al₁₀Cu₃₀Ni₅ to 77 K for Zr₅₅Al₁₀Cu₃₀Pd₅ alloy. A decrease in the GFA was also observed in the Zr–Cu–Al system with the addition of TM elements, such as Co and Fe, as can be deduced from the diffraction patterns of Fig. 1. For Zr₄₈Cu₄₈Al₄ alloy, the GFA decreases when Cu is partly substituted by up to 1 at.% Co. ^{Reference González, Pérez, Rossinyol, Suriñach, Baró, Pellicer and Sort46} This effect is more remarkable with the addition of Fe since only 0.5 at.% is enough to dramatically decrease the volume fraction of the amorphous phase. The predicted heats of mixing are −41 kJ/mol for Co–Zr, +6 kJ/mol for Co–Cu, −19 kJ/mol for Co–Al, −25 kJ/mol for Fe–Zr, +13 kJ/mol for Fe–Cu and −11 kJ/mol for Fe–Al pair. ^{Reference Lu, Bei and Liu35} Consequently, the atomic bondings with Co are stronger than with Fe, which can explain the lower GFA with the addition of Fe. Partial substitution of Cu by Co also decreases the GFA of the Zr–Cu system as observed by Javid et al. ^{Reference Javid, Mattern, Pauly and Eckert47,Reference Javid, Mattern, Samadi Khoshkhoo, Stoica, Pauly and Eckert48} These authors observed that Co shifts the temperatures of the eutectoid reaction, CuZr ↔ Cu₁₀Zr₇ + CuZr₂, to lower values and thus, increases the thermal stability of the B2 ZrCu phase.

FIG. 1.

A) Diffraction patterns corresponding to (a) Zr₄₈Cu₄₈Al₄, (b) Zr₄₈Cu_47.5Al₄Co_0.5, and (c) Zr₄₈Cu₄₇Al₄Co₁ as-cast rods. B) Diffraction patterns corresponding to (a) Zr₄₈Cu₄₈Al₄, (b) Zr₄₈Cu_47.5Al₄Fe_0.5, and (c) Zr₄₈Cu₄₇Al₄Fe₁ as-cast rods.

Depending on the transition element added and composition of the alloy, the effect on the GFA may be different. For Zr_66.7−x Ni_33.3Pd _x alloys, partial substitution of Zr by 1 and 3 at.% Pd (a late TM) enhances the GFA and the activation energy for crystallization ^{Reference Wang, Wang and Li49} due to the increase of topological short-range order. Similar GFA increase is observed in Ni₅₇Zr₂₀Ti_23−x Pd _x alloys when Ti is partly substituted by 3, 5, 7, and 10 at.% Pd. ^{Reference Lee, Kim and Kim50} The addition of Pd to Ni₅₇Zr₂₀Ti₂₃ alloy suppresses the formation of the primary cubic Ni(Ti,Zr) phase and increases the GFA. According to Inoue ^{Reference Inoue51} the supercooled liquid state is stabilized when multicomponent systems have large negative heat of mixing. The large negative heat of mixing of Pd–Zr (−91 kJ/mol) and Pd–Ti (−65 kJ/mol) ^{Reference Takeuchi and Inoue36} may explain the suppression of Ni(Ti,Zr) phase formation.

Metallic glasses corresponding to the Al–Y–Ni–Co–Pd system, exhibit a decrease in the GFA with the addition of Pd and leads to the formation of different crystalline phases depending on the concentration of the alloying element. For Al₈₅Y_8−x Ni₅Co₂Pd _x ribbon samples, a broad diffraction peak was observed for Al₈₅Y₈Ni₅Co₂ alloy and the peak tends to form two shoulders with increasing addition of Pd up to 4 at.%, ^{Reference Louzguine-Luzgin and Inoue33} suggesting a decrease in the GFA. Similarly, for 1 mm diameter rods of Al₈₆Ni₆Y_6−x Co₂Pd _x , partial substitution of Y by 0.5 and 1 at.% Pd results in a dramatic decrease of the GFA, ^{Reference González, Sort, Louzguine-Luzgin, Perepezko, Baró and Inoue52} as can be deduced from the diffraction patterns of Fig. 2. For Al₈₆Ni₆Y₆Co₂ alloy, peaks corresponding to α-Al and Al₃Ni are superimposed on a broad halo, suggesting the presence of an amorphous or nanocrystalline matrix. For Al₈₆Ni₆Y_5.5Co₂Pd_0.5 and Al₈₆Ni₆Y₅Co₂Pd₁ alloys, additional peaks corresponding to Al₉Co₂ and Al₃Y are detected while the broad halo is practically nonexistent. This reduction of the GFA could be explained considering the high binding potential of the Pd–Y pair (i.e., −84 kJ/mol) compared to the relatively low binding potential of the Co–Y (−1 kJ/mol) and Ni–Y (0 kJ/mol) pairs, ^{Reference Takeuchi and Inoue36} which would lead to a dramatic driving force for nucleation from Pd–Y pair sites. However, the promotion of α-Al phase formation with Pd addition cannot be explained from the heats of mixing due to the strength of the attractive interaction of the Al–Pd atomic pair. The small atomic size difference between Al and Pd does not favor the atomic packing, which may explain why the GFA decreases. ^{Reference Louzguine-Luzgin and Inoue33}

FIG. 2.

Diffraction patterns of 1 mm diameter Al₈₆Ni₆Y_6-xCo₂Pd_x (x = 0, 0.5 and 1) rods.

The addition of Pd to Mg₇₂Zn₂₃Ca₅ alloy also decreases the GFA, ^{Reference González, Pellicer, Fornell, Blanquer, Barrios, Ibañez, Solsona, Suriñach, Baró, Nogués and Sort53} as can be deduced from the diffraction patterns in Fig. 3. For the alloy without Pd, a broad halo centered at around 39° and a broad peak at about 37° are detected . The results suggest that the alloy consists of an amorphous matrix and nanocrystals embedded in it. However, for Mg₇₀Zn₂₃Ca₅Pd₂ and Mg₆₆Zn₂₃Ca₅Pd₆ alloys, narrow reflections are present, suggesting the development of a fully crystalline structure. These diffraction patterns are assigned to CaZn₅ MgZn, Mg₆Pd, and Mg₆Ca₂Zn₃ phases. From the relative change in intensity of the diffraction peaks with increasing content of Pd, it can be deduced that the volume fraction of the different phases change with the alloy composition. The backscattered SEM image in Fig. 4 shows the microstructure of the 3 samples of different compositions. For Mg₇₂Zn₂₃Ca₅ alloy, a rather featureless contrast is observed, which is consistent with the diffraction result. However, the microstructures for Mg₇₀Zn₂₃Ca₅Pd₂ and Mg₆₆Zn₂₃Ca₅Pd₆ alloys are completely different. The microstructures are crystalline and consist of a large volume fraction of dendrites. The dendrites correspond to Mg₆Pd, the gray regions to CaZn₅, the black regions to MgZn and the Mg₆Zn₃Ca₂ phase corresponds to the areas of darkest tonality that lie within the dark regions associated MgZn. The mechanism responsible for the GFA decrease with Pd addition in this system should be different from that of the Al₈₆Ni₆Y₆Co₂ alloy since the binding potential of the alloying element with the other elements of the alloy are relatively similar [i.e., Pd–Mg (−40 kJ/mol), Pd–Zn (−33 kJ/mol) and Pd–Ca (−63 kJ/mol)]. ^{Reference Takeuchi and Inoue36} The formation of Mg₆Pd probably comes from partial crystallization of the Pd–Mg atomic clusters upon cooling since Mg₆Pd is the first crystalline phase detected in the Mg–Pd system. ^{Reference Yamaura, Kimura and Inoue54} The heat of mixing of Mg₆Pd (−21 kJ/mol) is larger than that of MgZn (−4 kJ/mol), ^{Reference Boer, Boom, Matterns, Miedema and Niessen55} thus the formation of Mg₆Pd is more thermodynamically favored than the formation of MgZn. However, due to the high concentration of Zn atoms in the alloy, they have high probability to be surrounded by Mg atoms, which can lead to the formation of the intermetallic MgZn. As Pd enters the alloy in the substitution of Mg, the quantity of Mg₆Pd phase that is formed increases, which brings about a decrease in the amount of Mg available to constitute the Mg₆Ca₂Zn₃ phase.

FIG. 3.

Diffraction patterns of the as-cast Mg_72-xZn₂₃Ca₅Pd_x (x = 0, 2 and 6) rods.

FIG. 4.

SEM images (backscattered electrons) of (a) Mg₇₂Zn₂₃Ca₅, (b) Mg₇₀Zn₂₃Ca₅Pd₂, and (c) Mg₆₆Zn₂₃Ca₅Pd₆ rod. The insets show the magnified details of the microstructure of the Mg₇₀Zn₂₃Ca₅Pd₂ and Mg₆₆Zn₂₃Ca₅Pd₆ samples (in panels (b) and (c)).

1. BMGs

The minor addition of elements is very helpful to tune the mechanical properties of BMGs, such as the strength, ductility, toughness, etc. These properties can change, despite a small compositional change might not be enough to change the electronic structure or chemistry of the glass-forming liquid. ^{Reference Garret, Demetriou, Chen and Johnson56} Garret et al. ^{Reference Garret, Demetriou, Chen and Johnson56} studied the effect that small additions of Si and Sn has on the toughness of Cu₄₇Ti₃₄Zr₁₁Ni₈ BMG. For the three compositions studied, Cu₄₇Ti₃₄Zr₁₁Ni₈, Cu₄₇Ti₃₃Zr₁₁Ni₈Si₁, and Cu₄₇Ti₃₃Zr₁₁Ni₈Si₁Sn₂, they observed a decrease in toughness with increasing content in the alloying element. This behavior was attributed to an increase in the shear modulus (G), yield strength (σ_y), and glass transition temperature (T _g) and a decrease in Poisson's ratio (υ). The minor shifts of the elastic constants (G and υ) with small composition change suggest atomic structural arrangements that have an effect on the fracture behavior. For the most highly alloyed composition, i.e., Cu₄₇Ti₃₃Zr₁₁Ni₈Si₁Sn₂, cominor alloying with Si and Sn does not appear to have a synergistic effect on the fracture toughness (although the issue of co-addition was not dealt in the manuscript) since the effect on the of G, σ_y, T _g, and υ values could be expected considering that the concentration of minor elements in Cu₄₇Ti₃₃Zr₁₁Ni₈Si₁Sn₂ is 3 times higher than those in Cu₄₇Ti₃₃Zr₁₁Ni₈Si₁ alloy.

The toughness of the Zr–Cu–Al BMG system was studied by He et al. ^{Reference He, Cheng, Ma and Xu57} for different concentrations of Zr and Al. The atomic structure of the Zr–Cu–Al BMG system consists of rigid icosahedral clusters in different volume fractions depending on the Zr and Al content of the alloy. According to these authors, higher toughness is expected for compositions with high Zr-content since the internal structure contains a lower fraction of the rigid icosahedral clusters. They also suggested to avoid the addition to the Zr–Cu–Al system of TM elements with the high-lying partially-filled d band and strong orbital hybridization with Al since it would be detrimental to toughness. Substitution of Cu with Ni/Co enhances the degree of covalency, and thus decreases the toughness, because these elements elevate the TM-d band which interacts more strongly with the sp valence electrons of Al. ^{Reference He, Cheng, Ma and Xu57} Recent studies report that microalloying binary Zr–Cu alloys with Al is related to the changes in the cluster's composition, which results in considerable deviation from the random mixing behavior ^{Reference Bokas, Evangelakis and Lekka58} due to the strongly attractive interaction between Al and Zr atoms. ^{Reference Georgarakis, Yavari, Louzguine-Luzgin, Antowicz, Stoica, Li, Satta, LeMoulec, Vaugham and Inoue59} The late transition element Ni was also reported to decrease the toughness of Zr–Ti–Be–LTM BMGs. ^{Reference Kim, Suh, West, Lind, Dale Conner and Johnson60} Similarly, minor addition of Fe (0.5 at.%) into Vitreloy 1 (Zr_41.2Ti_13.8Cu_12.5Ni₁₀Be_22.5) results in the degradation in fracture toughness from 48.5 to 25 MPa m^1/2. This phenomenon was associated with the variation in free volume distribution in the glass with minor Fe addition.

Minor alloying addition can also have a dramatic effect on the thermoplastic behavior of BMGs. For example, minor addition of RE elements has a significant effect on the performance of the Zr–Cu–Ni–Al system. The thermoplastic formability of (Zr₆₅Cu_17.5Ni₁₀Al_7.5)_100−x RE _x (x = 0.25–3.25 at.%, RE: Y, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu) BMGs, was studied by analyzing the relative length shrinkage parameter (ΔL/L ₀), ^{Reference Hu, Fu and Zeng61} which is related with the malleability. The value of the parameter ΔL/L ₀ tends to increase with increasing content in the alloying element but the above certain concentration drops dramatically. Among all the RE elements investigated, maximum ΔL/L ₀ is attained with the addition of a critical concentration of 2 at.% Er and it drops with further addition of the alloying element. This critical concentration, however, varies with the type of element added. When Y is added, the maximum ΔL/L ₀ is reached for a concentration of about 1.2 at.%. The variation in the thermoplastic formability was attributed to the different abilities of RE elements to scavenge oxygen, a phenomenon that has a direct effect on the supercooled liquid region interval.

For certain BMG systems with low GFA, the addition of RE elements can result in partial crystallization of the material and lead to a significant change in the mechanical performance. Partial substitution of Mg by 1 at.% Y in the Mg₆₉Zn₂₇Ca₄ alloy is enough to partly crystallize a rod sample of 1 mm diameter and increase the strength from 550 to 1012 MPa. ^{Reference Wang, Li, Huang, Wei, Xi, Cai and Pan62} This behavior was attributed to the formation of the crystalline phases Mg₁₂YZn and Ca₂Mg₆Zn₃. However, addition of Y to Cu₄₅Zr₄₈Al₇ BMG improves the GFA and decreases the compressive fracture strength from 1892 MPa for Cu₄₅Zr₄₈Al₇ to 1465 MPa for Cu₄₆Zr₄₈Al₇Y₅ due to the reduction in the binding energy. ^{Reference Hong-wei, Yu-lei and Yu63}

2. Metallic glass composites

The effect of transition elements on the mechanical performance of alloys depends not only on the type of element (early, middle and late TM) added but also on the composition of the alloy. For example, partial substitution of Zr by Nb does not have a significant change in the mechanical properties of Zr_(46−x)Nb _x Cu_37.6Ag_8.4Al₈ alloys. ^{Reference Nie, Xu, Jiang, Chen, Xu, Fang, Xie, Luo, Wu, Wang, Cao and Jiang64} Other transition elements such as Co and Fe seem to have a larger influence on the mechanical behavior of BMG composites corresponding to the Zr–Cu–Al system. For CuZr-based metallic glass composites, the second-phase particles consist of B2-CuZr phase that transforms into B19′ martensite upon loading. ^{Reference Pauly, Gorantla, Wang, Kühn and Eckert65} This transformation, which occurs through twinning, ^{Reference Pauly, Gorantla, Wang, Kühn and Eckert65,Reference Seo and Schryvers66} leads to overall work hardening and thus enhances the plasticity of the BMG. Larger values of plasticity can be attained when the twinning propensity of the particles upon loading is favored. Wu et al. ^{Reference Wu, Zhou, Song, Wang, Zhang, Ma, Wang and Lu21} found that the capability of the B2-CuZr phase for deformation twinning could be tailored through microalloying with transition metals since they allow the tuning of the stacking fault energy of the primary slip system of B2-CuZr phase. The purpose of microalloying is to reduce the stacking fault energy of the primary slip system of reinforcing crystals to improve the twinning propensity thus favoring the martensitic transformation.

The stacking fault energy of base B2-CuZr phase (i.e., 381 mJ/m²) decreases when half of Cu on the (011) [100] slip plane is replaced by Cr, Fe, Co, Ni, and Ag. Among these elements, the maximum decrease of the stacking fault energy to 75 mJ/m² is obtained with Co addition. This substitution promotes martensitic transformation of the crystalline phase and favors work-hardening during the test which contributes to delay necking of the BMG composite. ^{Reference Wu, Zhou, Song, Wang, Zhang, Ma, Wang and Lu21}

Another interesting element for microalloying is Fe since it not only is useful for decreasing the stacking fault energy of B2-CuZr but also is cost-effective. To further understand the influence of Co and Fe addition and their concentration on the mechanical properties of the Zr–Cu–Al system, the mechanical properties of Zr₄₈Cu_48−x Al₄M _x (M ≡ Co or Fe, x = 0, 0.5, 1 at.%) BMG composites were studied. ^{Reference González, Pérez, Rossinyol, Suriñach, Baró, Pellicer and Sort46} Figure 5 shows the compressive stress–strain curves of the Zr₄₈Cu₄₈Al₄, Zr₄₈Cu_47.5Al₄Co_0.5, Zr₄₈Cu₄₇Al₄Co₁, Zr₄₈Cu_47.5Al₄Fe_0.5 and Zr₄₈Cu₄₇Al₄Fe₁ as-cast rods. From these results, it can be deduced that microalloying not only has an influence on the plastic deformation but also on the yield stress. The maximum compressive plasticity of 6.2% is attained for 0.5 at.% Fe. However, the yield stress decreases gradually from 1390 MPa (for 0.5 at.% Fe) to 1355 MPa (for 1 at.% Fe) with increasing content of Fe. The change in the plastic deformation and yield stress is due to the propensity for the mechanically-driven martensitic transformation of the pristine austenite phase. Other factors such as the co-existence of the amorphous and crystalline counterparts, the nature of the crystalline phase in the as-cast condition (i.e., austenite or martensite), the volume fraction of crystalline (B2) phase and the tendency for deformation-induced nanocrystallization inside shear bands play an important role in the mechanical performance of these alloys.

FIG. 5.

Compressive stress–strain curves of the Zr₄₈Cu₄₈Al₄, Zr₄₈Cu_47.5Al₄Co_0.5, Zr₄₈Cu₄₇Al₄Co₁, Zr₄₈Cu_47.5Al₄Fe_0.5, and Zr₄₈Cu₄₇Al₄Fe₁ as-cast rods. The insets are optical micrographs showing the fracture angle for (a) Zr₄₈Cu_47.5Al₄Co_0.5 and (b) Zr₄₈Cu_47.5Al₄Fe_0.5 rods. The compression curves have been shifted horizontally for the sake of clarity.

To further confirm the role of the stress-induced martensitic transformation on the mechanical performance, all the as-cast samples of the same composition were compressed to 2100 MPa for 4 min, i.e., under similar conditions in the compression test. The occurrence of the deformation-induced martensitic transformation and intragranular nanotwinning was evidenced from TEM (Fig. 6). The SAED pattern [Fig. 6(b)] of various crystallites reveals the coexistence of austenite B2 and martensite B19′ phases. Several intragranular nanotwins are generated inside many of the crystals [Figs. 6(a), 6(c), and 6(d)]. These nanotwins can hinder dislocation motion through the twin boundaries resulting in a hardness increase by the dislocation pile-up mechanism similar to that observed at grain boundaries. ^{Reference Sort, Zhilyaev, Zielinska, Nogués, Suriñach, Thibault and Baró67}

FIG. 6.

TEM images of the Zr₄₈Cu_47.5Al₄Fe_0.5 alloy compressed to 2100 MPa for 4 min. Panels (a), (c), and (d) show examples of intragranular nanotwins formed inside the crystalline particles during compression. Panel (b) is a SAED pattern of these crystals, revealing the coexistence of B2 (austenite) and B19′ (martensite) phases.

For aluminum alloys corresponding to the Al–Ni–Y–Co system, the addition of Pd was reported to be an effective transition element to control the microstructure and thus the mechanical performance of these alloys. Figure 7 shows the load–displacement (P–h) curves of Al₈₆Ni₆Y₆Co₂, Al₈₆Ni₆Y_5.5Co₂Pd_0.5, and Al₈₆Ni₆Y₅Co₂Pd₁ alloys with a maximum applied force of 300 mN. This load is high enough to get information from all the phases composing the microstructure and thus it provides a representative average value. The mechanical properties were evaluated measuring the hardness (H), reduced elastic modulus (E _r), ratio U _plastic/U _total, and maximum nanoindentation depth (h _max) as shown in the table associated to Fig. 7. Among the three compositions, the softest alloy is the Al₈₆Ni₆Y_5.5Co₂Pd_0.5 because it exhibits the lowest H and largest h _max. However, the maximum hardness is attained by the Al₈₆Ni₆Y₆Co₂ alloy (i.e., 5.5 GPa), probably because of its amorphous state, but decreases sharply to 2.5 GPa with the addition of 0.5 at.% Pd. For this composition the value of E _r is also the lowest. Further addition of Pd to 1 at.% increases the hardness to 3 GPa. The composition with the largest U _plastic/U _total corresponds to Al₈₆Ni₆Y_5.5Co₂Pd_0.5, corroborating its larger ability to store plastic energy during deformation.

FIG. 7.

P–h curves of (a) Al₈₆Ni₆Y₆Co₂, (b) Al₈₆Ni₆Y_5.5Co₂Pd_0.5, and (c) Al₈₆Ni₆Y₅Co₂Pd₁. The corresponding table lists the hardness (H), reduced elastic modulus (E_r), ratio U_plastic/U_total and maximum nanoindentation depth (h_max).

Microalloying with Pd also has a large effect on the mechanical properties of alloys corresponding to the Mg–Zn–Ca–Pd system. The P–h nanoindentation curves with a maximum load of 500 mN are shown in Fig. 8(a). Some of the indentation impressions obtained at half the radius of the Mg₇₀Zn₂₃Ca₅Pd₂ rod are shown in Fig. 8(b). These indentation marks are large enough to embrace all the existing crystalline phases, thus the mechanical properties obtained are representative of the average behavior of the composite. The addition of 2 at.% Pd increases the hardness from 2.71 GPa (x = 0) to 3.56 GPa (x = 2). The hardness increase is mainly attributed to the lack of free volume in the crystalline alloy (x = 2) compared to the mainly amorphous one (for x = 0). The hardness further increases for x = 6, up to 3.90 GPa, which is consistent with the decrease of the maximum indentation depth from 2.905 μm (for x = 2) to 2.673 μm (for x = 6). This behavior could be mainly attributed to the presence of MgZn and Mg₆Pd. Hardness is usually regarded to be an important property for evaluating wear resistance but some authors have shown that the wear resistance can be better estimated from the H/E _r ratio. ^{Reference Oberle68} Another parameter related to the wear performance is the resistance to plastic deformation, ^{Reference Tsui, Pharr, Oliver, Bhatia, White, Anders, Anders and Brown69} which is proportional to H ³/E _r ².

FIG. 8.

(a) (P–h) nanoindentation curves of Mg_72-xZn₂₃Ca₅Pdx (x = 0, 2 and 6) alloys and (b) backscattered SEM image showing some indents made close to the center of the Mg₇₀Zn₂₃Ca₅Pd₂.

For Al-based alloys, the small addition of Pd ^{Reference González, Sort, Louzguine-Luzgin, Perepezko, Baró and Inoue52} has a large influence on the microstructure and mechanical performance of Mg-based alloys. This behavior could be partly attributed to the low glass forming ability of alloys corresponding to these systems, which implies that small compositional change, such as microalloying would turn the microstructure from amorphous to crystalline. This work shows the usefulness to work with samples of dimensions close to the critical amorphous diameter so that microalloying could be more effective by turning the material from amorphous to partly or fully crystalline.