1. Introduction
Ir-based superalloys have received intensive interest in the last decades due to their high melting temperature as well as their improved strength, oxidation resistance and corrosion resistance at higher temperatures [1,2,3,4,5]. Consequently, these intermetallics can be deemed a suitable choice for high-temperature applications. For example, the cubic L12 intermetallic compounds Ir3X (X = Ti, Zr, Hf, Nb and Ta) containing refractory elements could be proposed as “refractory superalloys” based on their higher melting points and superior mechanical properties at higher temperatures [3,4,5]. Terada et al. [6] conducted measurements on thermal properties (i.e., thermal conductivity and thermal expansion) from 300 to 1100 K, and found that the L12 Ir3X (X = Ti, Zr, Hf, Nb and Ta) compounds were characterized by a larger thermal conductivity and a smaller thermal expansion. Chen et al. [7] exhibited the elastic constants and moduli of binary L12 Ir-based compounds at ground states by first-principles calculations, and reported the higher elastic moduli of these compounds together with their brittle characteristics in nature. Liu et al. [8] studied the elastic and thermodynamic properties of Ir3Nb and Ir3V under varying pressure (0–50 GPa) and temperature (0–1200 K), and found that both compounds were stable without phase transformations.
Meanwhile, the typical refractory intermetallics should also include A15 cubic structure compounds with refractory metal elements. For example, Pan et al. [9] reported the mechanical and electronic properties of Nb3Si using the first-principles method. By combining the first-principles method with quasi harmonic approximation, Papadimitriou et al. [10,11,12] critically investigated the mechanical and thermodynamic properties of Nb3X (X = Al, Ge, Si and Sn). Chihi et al. [13] theoretically evaluated the elastic and thermodynamic properties of V3X (X = Si, Ge and Sn) intermetallics utilizing the first-principles calculations. Jalborg et al. [14] determined the electronic structure of V3Ir, V3Pt and V3Au using the self-consistent semi relativistic linear muffin-tin orbital (LMTO) band calculations. Paduani et al. [15] investigated the chemical bonding behavior and estimated the electron-phonon coupling constants of V3X (X = Ni, Pd, Pt) by the full-potential linearized augmented-plane-wave (FP-LAPW) method.
Therefore, the Ir-based intermetallics with A15 crystal structure should also have the potential to be applied as structural materials. These compounds have been studied for their structural and electronic properties. For instance, Standanmann et al. [16] determined the lattice parameters of A15 X3Ir (X = Ti, V, Cr, Nb and Mo) compounds. Meschel et al. [17] reported the experimental standard enthalpy of formation for V3Ir. Paduani and Kuhnen [18] studied the band structure and Fermi surface of V3Ir using the FP-LAPW method, and discussed Knight shift behavior in the compound. Paduani et al. [19] reported the electronic properties of Nb3Ir via FP-LAPW calculations. Nevertheless, to our knowledge, the elastic and thermodynamic properties of X3Ir (X = Ti, V, Cr, Nb and Mo) intermetallics have rarely been discussed.
This research is divided into the following parts. In the second section, the computational methods of X3Ir (X = Ti, V, Cr, Nb and Mo) intermetallics are offered in detail. In the third section, the results and discussions are presented and discussed based on the effects of refractory metals on the physical and thermodynamic properties of X3Ir compounds, including structural properties, elastic propertie, anisotropic behaviors, anisotropic sound velocities, Debye temperatures, and electronic structures. In the fourth section, the conclusions are drawn and presented in detail. 2. Materials and Methods
The first-principles calculations were performed using the CASTEP code, which is based on the pseudopotential plane-wave within density functional theory [20,21]. Using the ultrasoft pseudopotential [22] to model the ion-electron exchange-correlation, both the generalized gradient approximation (GGA) with the function proposed by Perdew, Burke and Ernzer (PBE) [23,24] and the local density approximation (LDA) with Ceperley–Alder form [25] were used. Additionally, the basis atom states were set as: Ti3s33p63d35s2, V3s23p63d35s2, Cr3s23p63d54s1, Nb4s24p64d45s1, Mo4s24p64d55s1 and Ir5d76s2. Through a series of tests, the cutoff energy of 400 eV was determined. In addition, a 10 × 10 × 10 k-point mesh in the Brillouin zone was set for the special points sampling integration for the intermetallics. Both lattice constants and atom coordinates should be optimized via minimizing the total energy. Furthermore, the Brodyden–Fletcher–Goldfarb–Shanno (BFGS) minimization scheme was used for the geometric optimization [26,27]. Overall, the maximum stress has to be within 0.02 GPa, the maximum ionic force has to be within 0.01 eV/Å, the maximum ionic displacement has to be within 5.0 × 10−4 Å and the difference of the total energy has to be within 5.0 × 10−6 eV/atom for the geometrical optimization. Finally, the total energy and electronic structure were calculated, followed by cell optimization with a self-consistent field tolerance (5.0 × 10−7 eV/atom). Using the corrected tetrahedron Blöchl method, the total energies at equilibrium structures were derived [28].
3. Results 3.1. Structural Properties
The X3Ir (X = Ti, V, Cr, Nb and Mo) intermetallics have a A15 cubic structure with the cP8 (No. 223) space group. In a unit cell, six X atoms and two Ir atoms are dominated at the sites of 6c (0.25, 0, 0.5) and 2a (0, 0, 0), respectively. For the sake of performing structural property optimizations on IrX3 compounds, the GGA method as well as the LDA method were utilized. The results are exhibited in Table 1, showing that the derived lattice constants using both methods are close to the experimental values [29,30,31,32,33].
In most compounds, the lattice constants generated by the GGA method offer much smaller calculated deviations than the LDA method (Table 1). For instance, the a0(GGA) has the calculated deviation of −0.041%, and a0(LDA) has the calculated deviation of −2.223% in comparison with aexp in Ti3Ir. Clearly, the GGA method exhibited better reliability for structural optimization, and thus giving a superior quality of calculation over the LDA method. As a result, the following calculation work was accomplished only by GGA method.
3.2. Elastic Constants
In the crystalline materials, the elastic constant represented the capability of resisting the exterior imposed stress. In such manners, a whole package of elastic constants was achieved to characterize mechanical properties of crystals. By imposing small strains to the equilibrium unit cell, elastic constants can be computed by determining the corresponding variations in the total energy. Theoretically, the elastic strain energy was formulated by Equation (1):
U=ΔEV0=12∑i6∑j6Cij ei ej
where V0 represents the cell volume at equilibrium state; ΔE represents the energy difference; ei and ej represent the strains; Cij (ij = 1, 2, 3, 4, 5 and 6) represent the elastic constants.
In cubic structures, C11, C12 and C44 are nonzero elastic constants without mutual dependence. In Table 2, the calculated elastic constants (Cij) for X3Ir intermetallics are shown, accompanied by the available theoretical values [18,34,35,36] for comparison.
In the elastic constant, a larger C44 corresponds to a stronger resistance to monoclinic shear in the (100) plane, and therefore symbolizes a larger shear modulus. For instance, V3Ir has the largest C44 and shear modulus, exhibiting a superior capability to resist the shear stress. Furthermore, the compressive resistance along the x axis is reflected by C11. For each compound, the derived C11 exhibited the biggest value among elastic constants, suggesting that is has the greatest incompressibility under x uniaxial stress. Among the compounds, Mo3Ir was the least compressible along the x axis because it had the biggest C11 (512.7 GPa), and Ti3Ir was the most compressible owing to its small C11 (183.8 GPa)
Utilizing Born’s criteria [37,38], the essence of mechanical stability should be evaluated for cubic crystals:
C11 > 0; C44 > 0; C11 − C12 > 0; C11 + 2 C12 > 0
Using the values in Table 2, all X3Ir compounds were found to have mechanical stability by satisfying the Born’s criteria at the ground state.
The Cauchy pressure, illustrated as (C12–C44) [39], should be an effective indicator to evaluate the ductile/brittle nature of cubic crystals. In Pettifor’s work [40], a more positive Cauchy pressure symbolized better ductility in the compound [41]. In Table 2, the Cauchy pressures for X3Ir compounds were all positive in the order of V3Ir < Nb3Ir < Mo3Ir < Cr3Ir < Ti3Ir, which means that X3Ir compounds are naturally ductile. Such a result is in good compliance with the Cauchy pressure of Ti3Ir provided by Rajagopalan [34]. Similarly, other A15 cubic crystals (i.e., V3X (X = Si and Ge) [13], Nb3X (X = Al, Ge, Si and Sn) [10] and Nb3X (X = Al, Ga, In, Sn and Sb) [42]) have ductile characters owing to their positive Cauchy pressures.
3.3. Elastic Properties
Once the elastic constants were achieved, the elastic moduli (i.e., bulk modulus (B) and shear modulus (G)) could be computed by means of the Voigt–Reuss–Hill (VRH) method [43]. In cubic structures, the equations are exhibited as [44,45,46]:
BV=BR=13(C11+2C12)
GV=15(C11−C12+3C44)
GR=5(C11−C12)C444C44+3(C11−C12)
B=BV+BG2
G=GV+GG2
When the elastic moduli are achieved, the Young’s modulus (E) and Poisson’s ratio (ν) should be calculated in the second step [47]:
E=9BG3B+G
ν=3B−2G2(3B+G)
Lastly, the computed elastic moduli for X3Ir compounds using the VRH method are tabulated in Table 2 in combination with the available theoretical results for comparison [18,34,35,36]. Comparably, our calculated bulk moduli showed satisfactory agreement with the theoretical values for Ti3Ir [34], Nb3Ir [35] and Mo3Ir [36], and a value slightly smaller smaller than the theoretical one for V3Ir [18].
Analytically, the resisting capability against volume fluctuation under pressure is determined by the bulk modulus. For X3Ir (X = Ti, V, Cr, Nb and Mo) intermetallics, the bulk moduli showed the sequence of Ti3Ir < Nb3Ir < V3Ir < Cr3Ir < Mo3Ir. In References [48,49], a larger equilibrium cell volume was reported to correspond to a lower bulk modulus in the cubic crystal. Observably, such a conclusion is effective when the alloying elements are in the same cycle of the periodic table of elements (Figure 1a). For example, the bulk moduli are improved in the order of Ti3Ir < V3Ir < Cr3Ir depending on the reduced equilibrium cell volume. Similarly, the bulk modulus of Nb3Ir is smaller than that of Mo3Ir with the larger equilibrium cell volume of Nb3Ir (Figure 1a). Nevertheless, when the alloying elements are in the same group of the periodic table, the conclusion is valid for Nb3Ir < V3Ir, but ineffective for Cr3Ir < Mo3Ir, where Mo3Ir actually has a larger equilibrium cell volume.
In order to further illustrate the relationship between the equilibrium cell volume and the bulk modulus of X3Ir intermetallics, the linear dependence of the electron density on the bulk modulus is exhibited in Figure 1b. Clearly, dividing the bonding valence (ZB) by the volume per atom (VM) can deduce the electron density (n) in metallic compounds [50]. For X3Ir compounds, the electron density (n) can be formulated as:
n(X3Ir)=ZB(X3Ir)/VM(X3Ir)
where VM(X3Ir) represents the volume (cm3/mol) of X3Ir.
Rationalized by Vegard’s law [51], ZB(X3Ir) showed a bonding valence in (el/atom), and the Reference [52] tabulated the bonding valence of the pure element:
ZB(X3Ir)=(3ZB(X)+ZB(Ir))/4
Using this method, the linear dependence of the electron density on the bulk modulus was identified through the calculated values. Conclusively, it is more precise to rationalize the bulk modulus from the electron density, rather than the equilibrium cell volume.
Shear modulus (G) symbolizes the capability to resist shape fluctuation [44], and Young’s modulus (E) is a measurement of resistance to tension and compression in the elastic regime [53]. Notably, there is a linear dependence of the Young’s modulus on the shear modulus following the order of Ti3Ir < Nb3Ir < Cr3Ir < Mo3Ir < V3Ir (Figure 2).
Overall, the bigger bulk modulus over shear modulus for each X3Ir compound should reflect that the X3Ir compound has an improved capability to resist volume fluctuation over shape fluctuation (Table 2). This conclusion complies well with the available data regarding the dependence of the bulk modulus on the shear modulus in other A15 intermetallics, i.e., Ti3Ir (X = Ir, Pt and Au) [34], V3X (X = Si and Ge) [13], Nb3X (X = Al, Ga, In, Sn and Sb) [42] and Mo3X (X = Si and Ge) [54].
The Poisson’s ratio (−1 ≤ v ≤ 0.5) is used to quantify the stability of crystals against the shear deformation [55]. Materials with improved plasticity should possess a larger Poisson’s ratio. The X3Ir compounds have Poisson’s ratios in the order of V3Ir < Nb3Ir < Mo3Ir < Cr3Ir < Ti3Ir. This means that Ti3Ir should be the most ductile, while V3Ir is most brittle. Additionally, the Poisson’s ratio provides information on the bonding forces in solids [56]. The lower and higher limits are 0.25 and 0.5 for the central force in a solid, respectively. For XIr3 intermetallics, the interatomic forces of intermetallics should be central forces, since all the obtained values are located on this scale (Table 2).
The B/G ratio formulated by Pugh [57] is commonly adopted to quantitatively estimate the brittle or ductile essence of metallic compounds. The critical B/G ratio to distinguish the brittle from ductile material is 1.75. A smaller value is connected with the brittle nature, whereas a larger B/G ratio is related to ductility. Furthermore, the revised Cauchy pressure ((C12–C44)/E) [58] was plotted against the B/G ratio to clarify the extent of ductility intuitively (Figure 3). As a result, the ductility was found to be enhanced in the order of V3Ir < Nb3Ir < Mo3Ir < Cr3Ir < Ti3Ir. This conclusion agrees well with the analysis of the Poisson’s ratio. Clearly, Ti3Ir should be much more ductile than the other X3Ir compounds (Figure 3).
3.4. Elastic Anisotropy
The universal anisotropic index (AU) can be used to evaluate the elastic anisotropy, which is also referred to as the probability to introduce materials’ micro-cracks [59]. The index can be calculated via Equation (5) [60]:
AU=5GVGR+BVBR−6
where BV (BR) and GV (GR) represent the symbols of the bulk modulus and the shear modulus at Voigt (Reuss) bounds, respectively.
In the calculated elastic anisotropies, BV/BR, should be equal to 1 for cubic crystals (Table 3).
Indeed, GV/GR has a decisive effect on the universal anisotropic index (AU). Figure 4 shows that the universal anisotropic index increases linearly with the increment of the GV/GR value. A compound with a smaller AU represents a weaker extent of anisotropy. Therefore, the universal anisotropy was found to be reduced in the sequence of V3Ir < Cr3Ir < Nb3Ir < Mo3Ir < Ti3Ir. Generally, Ti3Ir has the largest universal anisotropy, and V3Ir has the smallest. Because the experimental value is lacking for comparison in these compounds, this calculation has to be evaluated in later research.
In addition, to further describe the anisotropy of X3Ir compounds, the directional dependence of the reciprocal of the Young’s modulus was constructed for a three-dimensional (3D) surface according to Equation (6) [48]:
1E=S11−2(S11−S12−S442)(l12 l22+l22 l23+l12 l32)
where Sij represents the usual elastic compliance constant obtained from the inverse of the matrix of the elastic constant; l1, l2 and l3 represent the direction cosines in the sphere coordination.
If a crystal has ideal isotropic performance, the 3D directional dependence of the Young’s modulus would show a spherical shape. In fact, the extent of deviation from the spherical shape symbolizes the anisotropic extent. In Figure 5, X3Ir compounds showed the distinctive 3D figures of Young’s moduli with various deviations from a sphere. This confirmed that X3Ir compounds have anisotropic behaviors. Obviously, Ti3Ir shows the largest deviation from the sphere shape along the <111> direction. On the contrary, other X3Ir compounds exhibited different forms of deviation, and the most visible deviations were observed along the zone axes. Finally, the extent of the elastic anisotropy for X3Ir obeyed the sequence of V3Ir < Cr3Ir < Nb3Ir < Mo3Ir < Ti3Ir. This conclusion complies well with the result obtained from the universal anisotropic index.
3.5. Anisotropic Sound Velocity and Debye Temperature
In the crystalline material, the sound velocities should depend on the crystalline symmetry in combination with the propagating direction. In the cubic structure, [111], [110] and [001] directions exhibited the pure transverse and longitudinal modes, accordingly. Regarding other directions, both quasi-transverse and quasi-longitudinal waves can work as the main sound propagating modes. Therefore, the sound velocities formulated in the principal directions are listed as follows [61]:
[100]vl=C11/ρ;[010]vt1=[001]vt2=C44/ρ[110]vl=(C11+C12+C44)/(2ρ)[11−0]vt1=(C11−C12)/ρ;[001]vt2=C44/ρ[111]vl=(C11+2C12+4C44)/(3ρ)[112−]vt1=[112−]vt2=(C11−C12+C44)/(3ρ)
where vl (vt) represents the longitudinal (transverse) sound velocity; ρ represents the density (see Table 1).
Overall, the longitudinal sound velocity along the [100] direction was only decided by C11. The transverse modes along [010] and [001] directions were dependent on C44. The longitudinal sound velocities along both the [110] and [111] directions were influenced by C11, C12 and C44.
Along the [100], [110] and [111] directions, the longitudinal sound velocities and the transverse sound velocities are exhibited in Table 4 for each X3Ir compound. For each compound, the longitudinal sound velocity followed the rising sequence of [100] < [110] < [111]. The sound velocities showed anisotropic properties, further confirming the elastic anisotropic behaviors of the compounds.
These theoretically computed physical properties (i.e., elastic moduli and Poisson’s ratio) and structural properties (i.e., density) should be adopted to calculate the Debye temperature (Θ) using the following formula [54,62,63]:
Θ=hk[3n4π(NAρM)]13 VD
where ρ represents the density (see Table 1); h represents the Planck’s constant (h = 6.626 × 10−34 J/s); k represents the Boltzmann’s constant (k = 1.381 × 10−23 J/K); n represents the number of atoms per formula unit; NA represents the Avogadro’s number (NA = 6.023 × 10−23/mol); M represents the molecular weight (M(Ti3Ir) = 335.8 g/mol, M(V3Ir) = 345 g/mol, M(Cr3Ir) = 347.8 g/mol, M(Nb3Ir) = 470.9 g/mol, M(Mo3Ir) = 480 g/mol); vD represents the average sound velocity in polycrystalline materials. The latter is formulated as:
vD=[13(1VL3+2VT3)]−13
where vT and vL represent the transverse and longitudinal sound velocities, respectively, as formulated by the equations below:
vT=Gρ
vL=B+43Gρ
For each X3Ir compound, the derived Debye temperature (Θ) is tabulated in Table 4. Also, the published experimental [16,64,65,66,67,68] and theoretical [34,36] values are included for comparison.
Generally, V3Ir had the largest Debye temperature, and Ti3Ir had the smallest. The calculated Debye temperatures were in the order of Ti3Ir < Nb3Ir < Mo3Ir < Cr3Ir < V3Ir. Clearly, our results revealed the reduced tendency of Debye temperatures with the M atom in the same group, i.e., Cr (Lighter element) and Mo (Heavier element) are from Group-VIB, and V (Lighter element) and Nb (Heavier element) are from Group-VB.
Comparably, the obtained Debye temperatures for Ti3Ir, V3Ir, Cr3Ir and Nb3Ir were all in excellent agreement with the available experimental results [16,64,65,66,67,68]. For instance, the calculated Θ was 233 K for Ti3Ir. This agrees well with the experimental values reported by Junod et al. [64] with the calculated deviation of 2.01%. Notably, the Debye temperature reported by Rajagopalan et al. [34] had the calculated deviation of 10.3%, indicating the poor quality of the prediction in this work. However, for Mo3Ir, the published experimental [16,68] and theoretical [36] Debye temperatures were quite scattered, although our calculated values were closer to the experimental values from Staudenmann’s report [16]. Nevertheless, more works are required on this compound.
Because both structural parameters and elastic moduli are incorporated to calculate the Debye temperature, the superior quality of our calculation on these structural and elastic parameters using the GGA method was evidenced by the smaller differences between the estimated and experimental values of Debye temperatures. 3.6. Electronic Structures
Figure 6a–e exhibit the density of states (DOS) spectra representing the calculated electronic structures for X3Ir compounds. The DOS spectra for these A15 cubic phases were similar to each other. In a typical DOS spectrum, there are normally three regions, including the lower electron band, the upper electron band, and the conduction unoccupied states around the Fermi level (EF). For example (Figure 6a), the lower the electron band was mainly contributed by 4s electrons of Ti ranging from −55 to −57.5 eV. The upper electron band was occupied by 3p electrons of Ti ranging from −32 to −35 eV. Around the Fermi level, the conduction unoccupied states were created through the hybridization of mainly Ti3d electrons with Ti3p, Ir5d and Ir4p electrons. X3Ir compounds were plotted around the Fermi level at zero in all the total DOS (TDOS) and partial DOS (PDOS) spectra. Clearly, no any energy gap can be found near the Fermi level. Therefore, their nature of metallicity was confirmed.
Furthermore, the electron density values can provide quantitative evidence of the metallic nature in the bonding characteristics. Even at the Fermi surface, the electron density values were much larger than zero. According to the electronic Fermi liquid theory [69], the metallicity of the compound has to be estimated using Equation (9) [70]:
fm=nmne=kBTDfne=0.026Dfne
where
- kB represents the Boltzmann constant (k = 1.381 × 10−23 J/K);
- T represents the absolute temperature;
- Df represents the DOS value at the Fermi level;
- nm and ne represent the thermally excited electrons and valence electron density of the cell, respectively;
- ne is calculated by ne = N/Vcell (N represents the total number of valence electrons; Vcell represents the cell volume).
Using the calculated metallicity values (fm), the correlation between metallicity and Poisson’s ratios can be constructed for X3Ir compounds (Figure 6f). It was found that the Poisson’s ratios were diminished with the reduction in metallicity in compounds with the order of V3Ir < Nb3Ir < Mo3Ir < Cr3Ir < Ti3Ir. This indicated that a compound with higher metallicity in its bonds should possess better ductility.
4. Conclusions The effects of refractory metals on physical and thermodynamic properties of X3Ir (X = Ti, V, Cr, Nb and Mo) intermetallics were investigated utilizing first-principles calculations. The conclusions are listed as follows:
(1) Using the GGA method to structurally optimized the unit cell, smaller calculation deviations for lattice constants were achieved as compared to those achieved using the LDA method.
(2) The calculated bulk moduli exhibited the increasing sequence of Ti3Ir < Nb3Ir < V3Ir < Cr3Ir < Mo3Ir. Furthermore, the bulk moduli showed a linear relationship with electron densities. The Young’s modulus showed a linear dependence on shear modulus following the order of Ti3Ir < Nb3Ir < Cr3Ir < Mo3Ir < V3Ir.
(3) Based on the discussions on the Cauchy pressure, Poisson’s ratio and B/G ratio, the ductile essence was found to be enhanced in the order of V3Ir < Nb3Ir < Mo3Ir < Cr3Ir < Ti3Ir.
(4) For X3Ir compounds, the extent of the elastic anisotropy for X3Ir obeyed the increasing sequence of V3Ir < Cr3Ir < Nb3Ir < Mo3Ir < Ti3Ir via the analyses of the universal anisotropic indexes and 3D surface constructions.
(5) The Debye temperatures obtained for Ti3Ir, V3Ir, Cr3Ir and Nb3Ir were all in good agreement with the results from experiments. Such good compliance proved the superior quality of our calculations of the structural and elastic properties, since the computation of Debye temperature is concerned with both structural and elastic parameters.
(6) The calculated electronic structures for X3Ir compounds showed similar features in the DOS spectra. Furthermore, the metallicity of the compounds was calculated, and was correlated with the Poisson’s ratios. This indicated that a compound with higher metallicity in its bonds should possess better ductility.
Enlarge this image.Figure 1. The relationship between bulk modulus and (a) volume of the unit cell or (b) electron density.
Enlarge this image.Figure 3. Revised Cauchy pressure (C12-C44)/E as a factor of the B/G ratio for X3Ir compounds.
Enlarge this image.Figure 4. The correlation between GV/GR and the universal anisotropic index (AU).
Enlarge this image.Figure 5. The 3D surface construction of the Young's modulus in X3Ir compounds. (The magnitudes of Young's moduli at different directions are presented by the contours along each graph with the unit of GPa).
Enlarge this image.Figure 6. Total density of states (TDOS) and partial density of states (PDOS) spectra for (a) Ti3Ir, (b) Cr3Ir, (c) Mo3Ir, (d) Nb3Ir and (e) V3Ir; (f) the correlation between metallicity and the Poisson's ratio in X3Ir compounds.
Enlarge this image.Figure 6. Total density of states (TDOS) and partial density of states (PDOS) spectra for (a) Ti3Ir, (b) Cr3Ir, (c) Mo3Ir, (d) Nb3Ir and (e) V3Ir; (f) the correlation between metallicity and the Poisson's ratio in X3Ir compounds.
| Compounds | a0 (Å) | aexp (Å) | Calculated Deviation (%) | Density (g/cm3) |
|---|---|---|---|---|
| Ti3Ir | 5.010 a | 5.012 c | −0.041 a | 8.872 a |
| 4.901 b | −2.223 b | 9.479 b | ||
| V3Ir | 4.7842 a | 4.7876 d | −0.072 a | 10.463 a |
| 4.6913 b | −2.012 b | 11.099 b | ||
| Cr3Ir | 4.652 a | 4.685 e | −0.712 a | 11.489 a |
| 4.651 b | −0.732 b | 11.496 b | ||
| Nb3Ir | 5.1585 a | 5.135 f | 0.457 a | 11.394 a |
| 5.0777 b | −1.116 b | 11.946 b | ||
| Mo3Ir | 4.9874 a | 4.9703 g | 0.344 a | 12.986 a |
| 4.9199 b | −1.014 b | 13.387 b |
a: From the GGA method in this work: Theoretical values. b: From the LDA method in this work: Theoretical values. c: From Reference [29]: Experimental values. d: From Reference [30]: Experimental values. e: From Reference [31]: Experimental values. f: From Reference [32]: Experimental values. g: From Reference [33]: Experimental values.
| Compounds | Cij | C12–C44 (GPa) | B (GPa) | G (GPa) | E (GPa) | v | B/G | ||
|---|---|---|---|---|---|---|---|---|---|
| C11 (GPa) | C44 (GPa) | C12 (GPa) | |||||||
| Ti3Ir | 183.8 | 52.8 | 166.0 | 114.2 | 171.9 | 26.5 | 75.7 | 0.427 | 6.483 |
| 207.2 a | 48.8 a | 153.1 a | 104.3 a | 171.1 a | 38.5 a | 107.4 a | 0.395 a | 4.446 a | |
| V3Ir | 471.5 | 109.4 | 136.8 | 27.4 | 248.4 | 129.8 | 331.7 | 0.277 | 1.913 |
| 279.89 b | |||||||||
| Cr3Ir | 478.6 | 89.6 | 190.2 | 100.4 | 286.3 | 108.5 | 289.0 | 0.332 | 2.639 |
| Nb3Ir | 433.7 | 84.5 | 123.7 | 39.2 | 227.0 | 108.0 | 279.7 | 0.295 | 2.102 |
| 216.4 c | |||||||||
| Mo3Ir | 512.7 | 87.6 | 175.8 | 88.2 | 288.1 | 114.2 | 302.6 | 0.325 | 2.523 |
| 297.5 d | |||||||||
a: From Reference [34]: Theoretical values. b: From Reference [18]: Theoretical values. c: From Reference [35]: Theoretical values. d: From Reference [36]: Theoretical values.
| Compounds | BV | BR | GV | GR | BV/BR | GV/GR | AU |
|---|---|---|---|---|---|---|---|
| Ti3Ir | 171.9 | 171.9 | 35.3 | 17.8 | 1 | 1.984 | 4.922 |
| V3Ir | 248.4 | 248.4 | 132.6 | 127.0 | 1 | 1.044 | 0.220 |
| Cr3Ir | 286.3 | 286.3 | 111.4 | 105.6 | 1 | 1.055 | 0.277 |
| Nb3Ir | 227.0 | 227.0 | 112.7 | 103.3 | 1 | 1.091 | 0.455 |
| Mo3Ir | 288.1 | 288.1 | 119.9 | 108.4 | 1 | 1.106 | 0.532 |
| Crystalline Orientation | Ti3Ir | V3Ir | Cr3Ir | Nb3Ir | Mo3Ir | |
|---|---|---|---|---|---|---|
| [111] | [111]vl | 5226.6 | 6138.7 | 5942.8 | 5460.3 | 5583.6 |
| [112− ]vt1,2 | 1629.2 | 3762.0 | 3311.6 | 3397.4 | 3301.0 | |
| [110] | [110]vl | 4763.3 | 5856.6 | 5744.8 | 5307.3 | 5466.2 |
| [11− 0]vt1 | 1416.9 | 5656.7 | 5010.3 | 5216.1 | 5093.6 | |
| [001]vt2 | 2440.3 | 3234.2 | 2792.4 | 2723.7 | 2597.2 | |
| [100] | [100]vl | 4551.4 | 6713.4 | 6454.1 | 6169.4 | 6283.3 |
| [010]vt1 | 2440.3 | 3234.2 | 2792.4 | 2723.7 | 2597.2 | |
| [001]vt2 | 2440.3 | 3234.2 | 2792.4 | 2723.7 | 2597.2 | |
| vL | 4833.4 | 6346.8 | 6124.7 | 5706.4 | 5822.9 | |
| vT | 1728.8 | 3522.6 | 3073.2 | 3079.0 | 2965.2 | |
| vD | 1962.7 | 3920.4 | 3444.0 | 3434.1 | 3320.0 | |
| Θ | 233.3 | 487.9 | 441.0 | 396.4 | 397.8 | |
| 238 a, 262.6 b | 460 ± 10 c, 445 d | 449 e | 409 ± 8 c, 377 d | 452 f, 325 g, 497.06 h |
a: From Reference [64]: Experimental values. b: From Reference [34]: Theoretical values. c: From Reference [65]: Experimental values. d: From Reference [66]: Experimental values. e: From Reference [67]: Experimental values. f: From Reference [16]: Experimental values. g: From Reference [68]: Experimental values. h: From Reference [36]: Theoretical values.
Author Contributions
In this work, D.C. has contributed on the conceptualization, investigation, data curation, formal analysis, and writing-original draft preparation. J.G. has contributed on the investigation, data curation, and writing-review and editing. Y.W. has contributed on the formal analysis, and writing-review and editing and funding acquisition. M.W. has contributed on the conceptualization, investigation, data curation, formal analysis, and writing-review and editing. C.X. has contributed on the conceptualization, investigation, formal analysis, writing-review and editing and funding acquisition.
Funding
This work was sponsored by the National Key Research and Development Program of China (Grant No. 2018YFB1106302) and the project (Grant No. 2017WAMC002) sponsored by Anhui Province Engineering Research Center of Aluminum Matrix Composites (China).
Conflicts of Interest
The authors have declared no conflict of interest.
References and Notes
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Dong Chen1,2,3, Jiwei Geng1, Yi Wu2, Mingliang Wang1,* and Cunjuan Xia2,*
1State Key Laboratory of Metal Matrix Composites, Shanghai Jiao Tong University, No. 800 Dongchuan Road, Shanghai 200240, China
2School of Materials Science & Engineering, Shanghai Jiao Tong University, No. 800 Dongchuan Road, Shanghai 200240, China
3Anhui Province Engineering Research Center of Aluminium Matrix Composites, Huaibei 235000, China
*Authors to whom correspondence should be addressed.
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