Abstract
A series of (NixAl)65Cr10Mo5V20 (x = 0.6,0.8,1.0,1.2,1.4,1.6) multi-principal element alloys (MPEAs) (or eutectic high-entropy alloys) were fabricated using a non-self-consumable vacuum melting method, and their solidification microstructures and mechanical properties were examined. As the Ni/Al ratio increases, the microstructure of the alloy changes from hypereutectic (primary BCC + eutectic, x = 0.6, 0.8) to eutectic (x = 1.0) to hypoeutectic (primary B2 + eutectic, x = 1.2, 1.4, 1.6). Within the range of 0.6-1.4, increasing the Ni/Al ratio promotes the production of the B2 phase, and the alloy's fracture strength increases initially and then decreases. The strengthening mechanisms are solid solution strengthening, B2 phase strengthening, and fine-grain strengthening. Among them, (Ni1.2Al)65Cr10Mo5V20 exhibits exceptional mechanical properties, with a yield strength of 1600 MPa, a fracture strength of 3106 MPa, a total compression plasticity of 25%, and a hardness of 697 HV. (Ni-1.2, Ni-1.4, and Ni-1.6 show the same mechanical properties within the confidence interval.) Furthermore, the phase prediction criteria for multi-principal element alloys containing Ni and Al were proposed: when ΔHmix ≤ 12.31(kJ/mol), 5.76(%) ≤ δr ≤ 7.44(%), as well as 0.75 ≤ Ω ≤ 1.53, the structure of MPEAs is BCC phase + B2 phase.
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1 Introduction
Multi-principal element alloys (or high-entropy alloys) with multiple main elements and atomic percentages ranging from 5 to 35% have garnered a great deal of attention since their introduction in 2004 (Ref 1, 2). It is well known that single-phased FCC-structured MPEAs have high ductility but low strength (Ref 3,4,5), whereas BCC-structured MPEAs have low ductility but higher strength. Indeed, a multiphase MPEA (or HEA) with different heat treatments or an appropriate composition design can achieve a combination of strength and plastic toughness (Ref 6,7,8,9,10). Due to the complexity of its composition and the variance in melting point of its components, MPEAs produced by the smelting method often have varying degrees of manufacturing defects and component segregation, stifling MPEAs’ industrialization and advancement (Ref 11,12,13). Lu (Ref 14) designed AlCoCrFeNi2.1 MPEA with a composite FCC/B2 structure, which was later defined as EHEA. It has a tensile strength of 1351 MPa and a ductility of 15.4%. This also marks the advent of a revolutionary concept for the design and development of large-scale multi-principal element alloys with high strength and plasticity. Several approaches for designing MEPAs (or EHEAs) have been presented thus far, including mixing enthalpy (Ref 15), simple mixing method (Ref 16), machine learning (Ref 17, 18), phase diagram calculation (CALPHAD) method (Ref 19), and pseudo-binary method (Ref 20).
Due to their low density, high melting point, good thermal conductivity, and great oxidation resistance, NiAl intermetallic compounds have been developed and applied in the field of high-temperature structural materials. However, the brittleness of NiAl-based alloys at room temperature restricts their utilization (Ref 21). Cr, Mo, and V can significantly improve the brittleness of NiAl. For instance, the fracture toughness of NiAl-9Mo (Ref 22, 23), NiAl-32Cr (Ref 24), NiAl-(34-x)Cr-xMo (Ref 25,26,27), and NiAl-40 V (Ref 28) is higher than that of NiAl intermetallic compounds. In the previous work, research group proposed an infinite solid solution strategy based on the concept of EHEAs (Ref 29). The design idea is that NiAl-34Cr (Ref 30), NiAl-9Mo (Ref 31), and NiAl-39 V (Ref 32) alloys are all eutectic, the microstructures contain the eutectic structure of the NiAl phase and Cr solid solution phase, NiAl phase and Mo solid solution phase, NiAl phase and V solid solution phase, respectively, and V, Cr, and Mo may produce an infinite solid solution with a BCC crystal structure (Ref 33, 34). A series of MEPAs were successfully designed and prepared by incorporating any combination of Cr, Mo, and V into NiAl alloys (Ref 29).
Westbrook (Ref 35) and Vedula (Ref 36) found that isometric binary NiAl alloy had substantially lower hardness and strength at room temperature than non-isometric. Qi (Ref 37) compared Ni-30Al-8Mo-2Nb to Ni-40Al-8Mo-2Nb and discovered that the latter had a much better compressive strength given the higher concentration of the NiAl phase. Jin (Ref 38) studied CrFeNi3−xAlx (x = 1, 0.9, 0.8, 0.7, 0.6) MPEAs and discovered that as the Ni/Al ratio increases, the alloy transitions from hypoeutectic to hypereutectic, with enhanced strength and decreased plasticity. As the Ni/Al ratio decreases in AlxCo15Cr15Ni70−x (Ref 38, 39) MPEAs, the alloy shifts from the FCC phase to the BCC + B2 phase as the Ni/Al ratio lowers, and the properties of the alloy alter greatly. Among them, Al19.3Co15Cr15Ni50.7 had the best overall performance, with a fracture strength of 2850 MPa and a fracture strain of 29%. Changing the Ni/Al ratio to boost performance appears to be a feasible method. In view of the good overall performance of NiAl-10Cr5Mo20V (Ref 29) in the previous work, this work explored optimizing the alloy by adjusting the Ni/Al ratio and studying the solidification microstructure and alloy properties.
2 Experimental
The multi-principal element alloys (NixAl)65Cr10Mo5V20 (x = 0.6, 0.8, 1.0, 1.2, 1.4 and 1.6) (referred to as Ni-0.6, Ni-0.8, Ni-1.0, Ni-1.2, Ni-1.4 and Ni-1.6) were produced using raw materials with ≥ 99.5% purity level in a high-purity argon environment. To ensure consistency, each sample underwent at least six separate melting. The samples were cleaned with sandpaper to eliminate surface oxides before detecting crystal structures with XRD utilizing CuKα radiation at 40 kV/40 mA and a scanning rate of 4°/min from 20 to 100°. After polishing, the samples were etched with aqua regia (nitric acid/hydrochloric acid = 1:3 V%), and the microstructure and elemental distribution of the alloys were determined using SEM–EDS. At room temperature, a WDW-100E universal testing machine was used to compress a Ф3*6 (mm) cylinder at a strain rate of 5 × 10−4 s−1. In order to eliminate measurement error, each sample was tested six times in ten seconds using a Vickers hardness tester (MH-6L) with a force of 100N.
3 Results and Discussion
3.1 Crystal Structure
Figure 1 depicts the XRD patterns of the as-cast (NixAl)65Cr10Mo5V20 (x = 0.6, 0.8, 1.0, 1.2, 1.4, 1.6) MPEAs, indicating that all of the alloys are B2 + BCC phase. Table 1 shows the binary mixing enthalpy of each element. As Ni and Al have the largest negative binary mixing enthalpy, they tend to form the NiAl intermetallic complex B2; V, Cr, and Mo have practically zero mixing enthalpy and can form an infinite solid solution BCC phase. It is hypothesized that the volume fraction of the B2 phase varies with the Ni/Al ratio based on the intensity relationship of the distinctive peaks corresponding to the B2 phase and the BCC phase exhibited in Fig. 1(a) from 40 to 50°. The B2 phase grows with a Ni/Al ratio between 0.6 and 1.4. When compared to the alloy structure with Ni-1.4, the B2 phase decreases slightly when the Ni-1.6; Fig. 1(b) is a partially enlarged plot of Fig. 1(a) from 75 to 85°. Table 2 displays the computed lattice constants using the Bragg equation for the BCC(211) and B2(211) phases. The characteristic peaks of the BCC phase shift to a high angle as the Ni/Al ratio grows, and the lattice constant decreases; the Ni/Al ratio has little influence on the characteristic peaks of the B2 phase.
3.2 Microscopic Characteristics
Figure 2 displays the SEM picture of (NixAl)65Cr10Mo5V20 MPEAs, and Table 3 summarizes the findings of the SEM–EDS study data. Figure 2(a) and (b) presents a white–gray alternating layered lamellar structure in a Ni-0.6 hypereutectic multi-principal element alloy. When combined with the data in Table 3, the gray phase is identified as the Ni- and Al-rich B2 phase, whereas the white phase is identified as the V-, Cr-, and Mo-rich BCC phase. During the solidification of the Ni-0.6 alloy, the BCC phase precipitates as a primary crystal with a volume fraction of approximately 26.5% and dendritic characteristics. The remaining liquid phase changes into a layered eutectic tissue consisting of white and gray phases. Figure 2(c), (d), (e), and (f) exhibits SEM images of Ni-0.8 and Ni-1.0. In Ni-0.8, the volume fraction of the primary BCC phase is reduced by up to 11.8%, and the eutectic layer is refined, indicating that this proportion is close to the eutectic point. In Ni-1.0 alloys, the typical eutectic organization is observed, with eutectic dendrites consisting of alternating NiAl and VCrMo lamellae, that is, alternating B2 and BCC phases. In a radial pattern extending outward from the interior to the cell or dendrite boundary, the lamellae at the grain boundaries (~ 640 nm) are coarser than those in the interior (~ 430 nm). This is due to the heat emitted by the solidification of the pro-eutectic clot affecting the eutectic tissue at the grain boundaries. Figure 2(g) and (h) shows an as-cast SEM image of the Ni-1.2 alloy. The gray dendrites in the image represent the primary B2 phase, which is relatively coarse due to direct crystallization from the liquid phase, and the gray–white interphase tissue distributed in the dendritic interstices is the BCC + B2 eutectic. Figure 2(i), (j), (k), and (l) shows SEM images of Ni-1.4 and Ni-1.6, which are also hypoeutectic alloys and have the same structure as Ni-1.2. As the Ni/Al ratio increases, the gray dendrites get coarser and the volume fraction of eutectic tissue decreases.
Figure 2 demonstrates that when the Ni/Al ratio increases, the eutectic organization transitions from irregular to regular back to irregular, and the (NixAl)65Cr10Mo5V20 alloy system also changes from hypereutectic (x = 0.6, 0.8) to eutectic (x = 1.0) and then finally to hypoeutectic (x = 1.2, 1.4, 1.6). The B2 phase volume fraction increases with the Ni/Al ratio, peaking at 67.5% in Ni-1.4 and decreasing to 61.3% in Ni-1.6, a trend that is consistent with the XRD results. This is because as the Ni/Al ratio increases, the amount of Ni increases while the amount of Al decreases. The B2 phase content reaches its maximum at 1.4, not at 1.0, due to the fact that Ni and Al have differing solid solubility in the BCC phase, and when Ni increases again, the decrease of Al causes the B2 phase content of Ni-1.6 to fall. Since the atomic radius of Al is substantially larger than that of V, Cr, and Mo, the magnitude of the lattice constant of BCC phase is proportional to the solid solution Al content in BCC phase. As the Ni/Al ratio rises, the BCC phase contains less Al and the lattice constant increases. According to the Bragg equation, the lattice constant decreases and the angle increases, this can explain the shift of the BCC phase peak toward higher angles and the drop in lattice constant in XRD. Meanwhile, gray precipitate was observed in the BCC phase and white precipitate was observed in the B2 phase, which was caused by the hysteretic diffusion effect, and the quick cooling mode of the water-cooled copper crucible would aggravate the hysteresis diffusion, as Wang et al. (Ref 40,41,42) anticipated. The alloy’s eutectic point is x = 1.0, which is consistent with previous experimental results (Ref 29). Figure 3 illustrates the elemental distribution of (NixAl)65Cr10Mo5V20 MPEAs, with V, Cr, and Mo more concentrated in the primary BCC phase in the hypereutectic organization (a) and (b), and Ni and Al more concentrated in the primary B2 phase in hypoeutectic organization (d), (e), and (f).
3.3 Mechanical Properties
Figure 4 depicts the compressive stress–strain curve for the (NixAl)65Cr10Mo5V20 (x = 0.6, 0.8, 1.0, 1.2, 1.4, 1.6) MPEAs. Table 4 shows the alloy’s room-temperature compression properties and microhardness. Ni-0.6 exhibited high brittleness with a fracture strength and fracture strain of 1519 MPa and 7%, respectively. The alloy's yield strength and fracture strength tend to rise when the Ni/Al ratio changes, although Ni-1.2 had the highest fracture strength while Ni-1.4 and Ni-1.6 decreased, with fracture strengths of 3093 and 3058 MPa, respectively. All of the alloys in the system had a strain at break of more than 22%, except for Ni-0.6, which was extremely brittle. The alloy system’s high compressive strength can be explained as follows: As the Ni/Al ratio increases, the eutectic lamellae spacing or primary crystals become finer and eventually coarser, with lower eutectic lamellae spacing in the Ni/Al ratio range of 0.8 to 1.2. With the increase of B2 phase, the B2 phase is an intermetallic compound with a greater strength than the BCC phase. The alloys with BCC/B2 coherent structure that have a matrix that is B2 phase have higher strength in general (Ref 43). The hardness of the primary B2 phase in Fig. 5(a) is greater than that of the primary BCC phase, and when combined with Fig. 5(b) and the change in alloy fracture strength, it may be assumed that the B2 phase is the alloy system's strengthening phase. (NixAl)65Cr10Mo5V20 has more B2 phase when the Ni/Al ratio is between 1.2 and 1.6 and has the most B2 phase at Ni-1.4. Precipitation strengthening: the nano-sized BCC phase precipitated within the B2 phase, and the nano-sized B2 phase precipitated within the BCC phase might enhance the material's strength, but the mechanism of the actions requires additional research and discussion. The effect of solid solution strengthening is gradually weakened as the Ni/Al ratio increases, as seen by a drop in Al content in the BCC phase and the decrease in the lattice constant of the BCC phase, implying that the B2 phase is getting larger.
When the Ni/Al ratio was increased from 0.6 to 0.8, the fracture strength and fracture strain of the Ni-0.8 alloy increased substantially. It could be due to the expansion of the B2 phase and the refinement of the eutectic structure. When the Ni/Al ratio is 1.0, the eutectic layer continues to refine, especially the irregular layer spacing at the grain boundary, which changes from about 520 nm for Ni/Al of 0.8 to about 430 nm for Ni/Al of 1.0. As a result, the fine-grain strengthening and the increase in the B2 phase result in higher fracture strength and compression. The Ni-1.2 alloy is transformed from eutectic to hypoeutectic with a primary B2 phase volume fraction of about 23.1% and a coarsened lamellae organization with a spacing of about 630 nm. Therefore, the strengthening mechanism of Ni-1.2 alloy is mainly B2 phase strengthening compared to Ni-1.0 alloy, but the coarsened lamellae spacing results in a slight decrease in compressibility. The fracture strength and hardness of Ni-1.4 decrease, which may be due to the coarsening of eutectic lamellar (~ 740 nm) and irregularity, and the negative impacts of BCC phase lattice constant drop outweigh the strengthening effect of B2 phase increase. In Ni-1.6, the B2 phase is reduced and the eutectic lamellar does not change much (~ 720 nm), which lowers the alloy's fracture strength. Simultaneously, we find that precipitation strengthening is prevalent throughout the alloy system, as can be demonstrated in Fig. 3. In summary, the strengthening and toughening mechanism of the alloy is a competing process of fine-grain strengthening, precipitation strengthening, B2 phase strengthening, and solid solution strengthening, with Ni-1.2 having the best overall mechanical properties.
3.4 Relationship Between Microstructure and Mechanical Properties
The mechanical traits of (NixAl)65Cr10Mo5V20 MPEAs are significantly affected by changes in the Ni/Al ratio. Figure 6 demonstrates the outcome of the B2 phase volume fraction change on the yield strength of (NixAl)65Cr10Mo5V20 MPEAs, signifying that the B2 phase could yield a good strengthening action. The strength of the multi-principal element alloy can be roughly expressed using the prediction law of mixtures (Ref 44) in the eutectic structure formed by the hard B2 phase and the BCC solid solution with good toughness:
Corresponding strain assumptions are devised in this work, where VB2 refers to the volume fraction of the B2 phase, while σ0.2, σB2, and σBCC represent the stresses of alloy respectively. σBCC and σB2 are constant values. The fitting curve of the alloy shows a good linear relationship with the yield strength, and the increase of B2 phase has a positive contribution to the yield strength.
To accurately assess the contribution of the strengthening mechanism to the overall performance, it is essential to calculate the solid solution strengthening of the (NixAl)65Cr10Mo5V20 alloy. This alloy can be considered a VCrMo solvent with Ni and Al acting as solutes that are partially soluble in VCrMo. As a result, the solution strengthening can be expressed using a displacement solution strengthening model that is based on dislocation–solute interactions (Ref 45, 46):
The shear modulus (G) of the NiAl system can be calculated for the (NixAl)65Cr10Mo5V20 alloy using a simple mixing rule (Ref 47), assuming that the alloy is an isotropic solid. Here, c represents the total molar percentage of Ni and Al in the BCC matrix. The mean orientation factor for the polycrystalline matrix in the BCC phase is M = 2.9 (Ref 47), and the interaction parameter (\({\varepsilon }_{\mathrm{s}}\)) can be expressed as:
This equation combines the effects of elastic and atomic size mismatch, represented by \({\varepsilon }_{\mathrm{G}}\) and \({\varepsilon }_{\mathrm{a}}\), respectively. Specifically, \({\varepsilon }_{\mathrm{G}}\) and \({\varepsilon }_{\mathrm{a}}\) are defined as:
The parameter \({\varepsilon }_{\mathrm{G}}\) can be neglected in comparison with \({\varepsilon }_{\mathrm{a}}\), while the parameter a can be determined from the lattice constants provided in Table 2 for the BCC phase. The contribution values for solid solution strengthening from Ni-0.6 to Ni-1.6 are as follows, in order: 58.6, 59.1, 55.3, 56.4, 55.8, and 51.9 MPa. These results indicate that the impact of solid solution strengthening on the strength of the alloy is relatively small.
When the grain size is smaller, the grain boundary area will be larger, and the slip resistance of the dislocation near the grain boundary becomes greater; thus, it can be concluded that finer grain size enhances strength. Literature has reported that the correlation between the yield strength and grain size of polycrystalline materials can be expressed with the following classical Hall–Petch equation (Ref 48, 49):
where Δδy is expressed as yield stress, k is the constant. In the case of (NixAl)65Cr10Mo5V20 MPEAs, the secondary dendrite spacing and grain size would reduce following the introduction of B2. In this study, the parameter k = 628 MPa·μm1/2 was employed to assess the contribution of fine crystal strengthening (Ref 50). The calculated increase in yield strength was 957 MPa and 730 MPa for Ni-1.0 with the smallest grain size (eutectic structure) and Ni-1.4 with the largest grain size, respectively, hinting that fine-grain strengthening plays a significant part in the alloy system. To conclude, the main factors contributing to the strengthening of the alloy system include the addition of the B2 phase as well as fine-grain strengthening.
Ni-1.2, Ni-1.4, and Ni-1.6 all possess high strength, with Ni-1.2 exhibiting relatively better plasticity. The increase in strength is mostly attributable to a rise in the B2 phase and fine-grain strengthening of the eutectic group. The increment of the hard B2 phase can limit dislocation and interface migration effectively. At the same time, the precipitate produced during solidification promotes the nucleation of eutectic masses while inhibiting grain development. The refined eutectic lamellae is made up of more interfaces, contributing to the inhibition of dislocation motion and promotes strength improvement. There are two plausible contributors for the increase in plasticity. The fundamental explanation is the fine-tuning of the eutectic lamellae when there is an increment in the Ni/Al ratio (as shown in Fig. 2). The eutectic structure's grain refinement disperses plastic deformation across more grains, thus decreasing stress concentration and improving plasticity. The main reason for the relatively better plasticity of Ni-1.2 is the refinement of the eutectic lamellar structure due to the increase in the Ni/Al ratio, as shown in Fig. 2. With the grain refinement of the eutectic microstructure, plastic deformation is dispersed over more grains, resulting in less stress concentration and higher ductility.
In conjunction with numerous published research, this study collated the mechanical properties of several MPEAs (or HEAs) with comparable structures, as shown in Fig. 7. AlCoCrFeNi with the same BCC + B2 structure as the alloys studied in this work has a strength and plasticity close to Ni-1.0, but lower than Ni-1.2, Ni-1.4, and Ni-1.6. It is worth noting that AlCoCrFeNiMo0.2 (Ref 51) has a BCC + B2 structure with slightly lower plasticity and strength than Ni-1.2, both with excellent all-round properties, but its yield strength and hardness are nearly 11% lower than Ni-1.2. NiAlMo10Cr10V10, NiAlMo14Cr14Fe14, and NiAlMo11Cr11V11Fe11 (Ref 52) are also made up of BCC + B2, which have high strength but only around 20% plasticity. The yield strength of NiAl-Cr(Mo)-0.5Hf alloy is only 1380 MPa, which is substantially lower than the 1600 MPa of Ni-1.2 (Ref 53); it is regarded as a conventional high-strength alloy. The mechanical properties of Ni-1.2 alloy are not inferior to those of multi-principal element alloys of the same type, making it a promising new structural material.
3.5 Phase Prediction
Table 5 calculates the relevant thermodynamic parameters of (NixAl)65Cr10Mo5V20 and some typical cast eutectic high-entropy alloys, as follows:
where n represents the total number of atoms, r represents the mean atomic radius, ci represents the fraction of atoms belonging to element i, ri represents its radius, ∆Hij represents the enthalpy of mixing between elements i and j, and (Tm)i represents its melting point.
In order to study MPEAs in depth and design MPEAs that are better in line with practical production requirements, the researchers summarized the parameters of existing MPEAs and then proposed a phase formation criterion. Zhang (Ref 58) et al. used δr and ΔH to determine whether the solid solution phase (SS), intermetallic compound phase (IM), and amorphous phase appeared in the alloy. Guo (Ref 55) et al. employed the valence electron concentration parameter to forecast the composition of the phase, with VEC ≥ 8, FCC structural solid solution will be developed; when VEC ≤ 6.87, BCC structural solid solution will be formed; if 6.87 < VEC < 8, FCC + BCC structural solid solution will be formed. However, this criterion does not apply to any of the alloys listed in Table 5, including AlCoCrFeNi3.0 (Ref 39), Al0.5CrFeNiTi0.25 (Ref 54), and Al1.25CoCrFeNi (Ref 56). This may be due to its perception of the B2 phase as an ordered BCC phase, but the NiAl phase is an IM. Furthermore, Zhang and Yang (Ref 59) separated the SS and the IM by Ω parameters, and only the SS phase appeared in the range of Ω ≥ 1.1 and δr < 3.6%, while there were mixing phases of IM and SS in the range 1.1 ≤ Ω ≤ 10 and 3.6% ≤ δr ≤ 6.6%. The calculation found that all of the (NixAl)65Cr10Mo5V20 alloy systems had δr greater than 6.6% and Ω less than 1.1, but the phase composition was SS + IM, which could be related to considering the B2 phase as an ordered BCC phase (Ref 51), or the criterion needs to be refined further. Simultaneously, data analysis reveals that the majority of the MPEAs with SS + IM structures identified by Zhang et al. contain Cu, and the binary mixing enthalpy of Cu and other constituent elements is relatively high (generally greater than 0). This raises the alloy’s overall mixing enthalpy, and Ω is likewise affected by the mixing enthalpy. In contrast, the mixing enthalpy and Ω values of the constituent elements are modest in this study. By comparing experimental data, Wang (Ref 60) came to the conclusion that ΔHmix and δr are important parameters for a single SS to form in MPEAs. Considering that Ω parameters can distinguish between the SS and the IM, and in light of the literature and the work in this paper, ΔHmix, δr, and Ω were used to analyze MPEAs with the BCC + B2 phase concurrently, and the B2 phase was classified as the IM. Figure 8 shows the statistical results of ΔHmix, δr, and Ω versus alloy phase: when ΔHmix ≤ 12.31(kJ/mol), 5.76(%) ≤ δr ≤ 7.44(%), and 0.75 ≤ Ω ≤ 1.53, the structure in the MPEA is the BCC + B2 (NiAl) phase. The significance of the criterion is that limiting the atomic size range balances phase separation and solid solution, and negative mixing enthalpy secures the IM phase. Additionally, limiting the Ω value allows the system to have a specific mixing entropy, which ensures the formation of solid solutions.
4 Conclusions
This study produced MPEAs from (NixAl)65Cr10Mo5V20 (x = 0.6,0.8,1.0,1.2,1.4,1.6). The alloys' solidification microstructures and mechanical properties were examined. The findings are as follows:
-
(1)
Microstructure of (NixAl)65Cr10Mo5V20 MPEAs is both B2 and BCC, which changes from hypereutectic (primary BCC + eutectic, x = 0.6, 0.8) to eutectic (x = 1.0) and then to hypoeutectic (primary NiAl + eutectic, x = 1.2, 1.4, 1.6) as the Ni/Al ratio rises where the BCC phase has more Mo, Cr, and V and the B2 phase has more Ni and Al.
-
(2)
As the Ni/Al ratio rises, the strength and plasticity of the alloy increase initially and then decrease, owing to precipitation strengthening, fine-grain strengthening, and B2 phase strengthening. The alloys Ni-1.0, Ni-1.2, Ni-1.4, and Ni-1.6 all exhibit excellent strength and plasticity, with Ni-1.2 having the best overall performance, with fracture strength 3106 MPa, strain at break of 25%, yield strength of 1600 MPa, and hardness of 697 HV. It is a novel structural material with significant potential for application.
-
(3)
In conjunction with this work and the literature, the following phase prediction criteria of BCC phase + B2(NiAl) phase for the microstructure of multi-principal element alloys are proposed: ΔHmix ≤ 12.31(kJ/mol), 5.76(%) ≤ δr ≤ 7.44(%), and 0.75 ≤ Ω ≤ 1.53.
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Acknowledgments
The research was financially supported by the Yichang Key Laboratory of Graphite Additive Manufacturing Program (Nos. YKLGAM202001).
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Ye, X., Feng, J., Lei, H. et al. Effect of Ni/Al Ratio on Solidification Structure and Properties of NiAl-Based Multi-principal Element Alloy. J. of Materi Eng and Perform 33, 2782–2793 (2024). https://doi.org/10.1007/s11665-023-08175-y
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DOI: https://doi.org/10.1007/s11665-023-08175-y