Structural, electronic, elastic, and thermal properties of CaNiH<sub>3</sub> perovskite obtained from first-principles calculations

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Benlamari S, Bendjeddou H, Boulechfar R, Amara Korba S, Meradji H, Ahmed R, Ghemid S, Khenata R, Bin Omran S. Structural, electronic, elastic, and thermal properties of CaNiH₃ perovskite obtained from first-principles calculations. Chinese Physics B, 2018, 27(3): 037104 Copy to clipboard

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Structural, electronic, elastic, and thermal properties of CaNiH₃ perovskite obtained from first-principles calculations

Benlamari S¹, Bendjeddou H¹, Boulechfar R¹, Amara Korba S¹, Meradji H^{1, †}, Ahmed R², Ghemid S¹, Khenata R^{3, ‡}, Bin Omran S⁴

1Laboratoire LPR, Département de Physique, Faculté des Sciences, Université Badji Mokhtar, Annaba, Algeria

2Department of Physics, Faculty of Science, Universiti Teknologi Malaysia, UTM, Skudai, 81310 Johor, Malaysia

3Laboratoire de Physique Quantique et de Modélisation Mathématique de la Matière (LPQ3M), Université de Mascara-29000-Algeria

4Department of Physics and Astronomy, College of Science, King Saud University, P.O. Box 2455, Riyadh 11451, Saudi Arabia

† Corresponding author. E-mail: hmeradji@yahoo.fr

Khenata_rabah@yahoo.fr

Abstract

A theoretical study of the structural, elastic, electronic, mechanical, and thermal properties of the perovskite-type hydride CaNiH₃ is presented. This study is carried out via first-principles full potential (FP) linearized augmented plane wave plus local orbital (LAPW+lo) method designed within the density functional theory (DFT). To treat the exchange–correlation energy/potential for the total energy calculations, the local density approximation (LDA) of Perdew–Wang (PW) and the generalized gradient approximation (GGA) of Perdew–Burke–Ernzerhof (PBE) are used. The three independent elastic constants (C₁₁, C₁₂, and C₄₄) are calculated from the direct computation of the stresses generated by small strains. Besides, we report the variation of the elastic constants as a function of pressure as well. From the calculated elastic constants, the mechanical character of CaNiH₃ is predicted. Pertaining to the thermal properties, the Debye temperature is estimated from the average sound velocity. To further comprehend this compound, the quasi-harmonic Debye model is used to analyze the thermal properties. From the calculations, we find that the obtained results of the lattice constant (a₀), bulk modulus (B₀), and its pressure derivative ( ) are in good agreement with the available theoretical as well as experimental results. Similarly, the obtained electronic band structure demonstrates the metallic character of this perovskite-type hydride.

PACS: 71.15.Nc;71.15.Mb;71.15Ap;74.62.Fj

Keyword:perovskite-type hydrides;elastic constants;hydrogen storage materials

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1. Introduction

In recent years, ternary hydrides ABH₃ have attracted considerable attention of a lot of scientists around the world because of their high hydrogen storage capacity and large number of other applications like switchable mirrors,^[1–3] rechargeable batteries, energy storage, etc.^[4,5] In ABH₃ ternary hydrides, A is usually an alkali or alkaline earth metal and B is a transition metal. Some of the ABH₃ ternary hydrides also show the perovskite-type structure in which H is regarded as the anion, and A and B are monovalent and divalent cations, respectively. If A is a heavier alkaline metal like Ca, Ba, Sr and B is Fe, Ni, or Co, the resultant ABH₃ compounds are reported stable, and this stability is associated with the filled d-band of the alkaline earth and transition metals. However, the priority to these hydrides is given mainly on the basis of their good storage capacities, good reversibility, and large reactivity.

The CaNiH₃ based alloys are expected to be attractive hydrogen storage materials in the coming hydrogen energy era because of their good hydrogenation properties and relatively low material cost. The perovskite-type hydride CaNiH₃ was discovered in the study of the decomposition of hydrogenated CaNiH₃ alloys in the H₂ atmosphere.^[6] This ternary hydride has a large hydrogen content of 3 wt.% and decomposes to CaH₂ and Ni when it is heated from room temperature to 773 K in an H₂ atmosphere of 3 MPa. Some investigations have been reported in the literature.^[6–9] The first work on the hydrogenation properties of CaNiH₃ was reported by Oesterreicher et al.^[7] More recently, Takeshita et al.^[6] reported the synthesis and decomposition of CaNiH₃ hydride at high temperatures up to 773 K, analyzed the hydrogenation properties and the change in crystal structure of CaNiH₃ by using differential thermal analysis (DTA) and x-ray diffraction (XRD). Sato et al. calculated its electronic band structures by employing the augmented plane wave method^[8] and predicted the metallic nature of the CaNiH₃ compound. An experimental study of the formation and thermal desorption process of CaNiH₃ was also carried out.^[9]

Although studies are reported on the hydrogenation/dehydrogenation processing, to the best of our knowledge, there are no experimental or theoretical data on the elastic, mechanical, and thermal properties of this interested compound, which are important to understand the real character of CaNiH₃ and its applicability for different applications. Thus the aim of this work is to give a comprehensive study on its physical properties by employing full potential (FP) linearized augmented plane wave plus local orbital (LAPW+lo) method framed within density functional theory (DFT) and implemented in the WIEN2k computational package. The organization of the rest of the paper is as follows. In Section 2, we briefly describe the methodology. In Section 3, we present and discuss the results of our study regarding the structural parameters, elastic constants, pressure dependence elastic constants, band structure, and thermal properties. Finally, in Section 4, we summarize the main conclusions of this work.

2. Calculation method

The first-principles calculations of this work are performed using the FP-LAPW+lo method^[10] based on the DFT^[11] as implemented in WIEN2k code.^[12] In this approach, the crystal unit is partitioned into two regions: nonoverlapping muffin tin spheres (MT) and interstitial regions (IR). In the two regions, the Kohn Sham wave functions, charge density, and potential are treated differently. To determine the structural parameters, the local density approximation (LDA) of Perdew–Wang (PW)^[13] and the generalized gradient approximation (GGA) of Perdew–Burke–Ernzerhof (PBE)^[14] are employed. To avoid the overlapping, the muffin-tin radii (R_MT) are taken to be 2.5, 2.03, and 1.10 for Ca, Ni, and H, respectively. To expand the charge density as well as the potential, the maximum angular moment is used inside the atomic spheres. To obtain the suitable total energy convergence in the interstitial regions, the basis functions are expanded to , where is the maximum value of the wave vector K. The charge density is restricted to (Ryd)^1/2. The Brillouin zone integrations for the total energy are carried out using 35 special k-points in the irreducible part of the Brillouin zone. In order to investigate the thermal effects, Gibbs program based on the “quasi-harmonic Debye model” is used.^[15]

3. Results and discussion

3.1. Structural properties

The CaNiH₃ ternary hydride, typically containing a single molecule, crystallizes in the perovskite-type cubic structure with (#221) space-group. The Wyckoff positions of the atoms (Ca, Ni, and H) inside the unit cell are 1a (0,0,0), 1b (1/2,1/2,1/2), and 3c (1/2,0,0), respectively. In order to calculate the ground state properties of the CaNiH₃ hydride, the total energies are calculated for various volumes around the equilibrium position, and then the obtained results are fitted to the Murnaghanʼs equation of state.^[16] The calculated total energy versus the unit cell volume of CaNiH₃ is shown in Fig. 1. The calculated lattice parameter a₀, bulk modulus B₀, and its first derivative for this ternary compound are listed in Table 1, together with the available experimental and other theoretical results. From Table 1, it is clear that our results are in good agreement with the previously reported experimental and theoretical results. Our calculated equilibrium lattice constants within the PBE-GGA (PW-LDA) are found just 0.39% (2.28%) lower than the experimental value,^[6] indicating the reliability of our calculations. Our computed lattice constants are also in good agreement with those calculated by Sato et al.^[8] Similarly, our predicted bulk modulus at the level of PBE-GGA is also somehow smaller than that obtained within PW-LDA. However, the bulk modulus obtained at the level of PW-LDA is consistent with the previously reported theoretical one.^[8] On the whole, by comparing the results obtained at the levels of PBE-GGA and PW-LDA, we find that the results obtained for the structural parameters by PBE-GGA are improved over those by PW-LDA.

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	Fig. 1. Calculated total energy versus volume for CaNiH₃ using GGA approximation.

Table 1.

Calculated lattice constant a₀, bulk modulus B₀, its pressure derivative , and elastic constants C_ij for CaNiH₃ compared with other theoretical and experimental results.

3.2. Elastic properties

The study of the elastic parameters is crucial to getting knowledge about the bonding among the nearest neighbors, structural stability, and anisotropic character of a material, and these parameters are vital to understanding the mechanical behavior. Moreover, studying the aforementioned parameters at the high pressure also provides information about the material response, mechanical stability, and strength under compression. As our system is cubic, it is well recognized that the three independent elastic constants are C₁₁, C₁₂, and C₄₄. To calculate the elastic constants, the Thomas Charpin method as integrated within the WIEN2k package is used^[12] and the obtained elastic constants for the CaNiH₃ compound are given in Table 1. These are the first results concerning the elastic properties of this compound. From our calculations, we find that the calculated elastic constants C_ij are positive. The stability criteria for mechanical properties^[17] are satisfied, that is, ( ( , alongside satisfying the bulk modulus B₀ criterion, i.e., . From Table 1, one can easily see that the bulk modulus B₀ calculated from the elastic constants has nearly the same value as the one obtained from the fitting of the data into the Murnaghanʼs equation of state (EOS). This might be an estimate of the reliability and accuracy of our predicted elastic constants for CaNiH₃. Furthermore from Table 1, it can also be noticed that the unidirectional compression found in terms of the elastic constant (C₁₁) in the principal crystallographic direction is much higher than that of C₄₄, demonstrating a weaker resistance to pure shear deformation in comparison with the resistance offered to unidirectional compression.

3.3. Mechanical properties

Knowledge of the elastic properties of materials promotes the understanding of the fundamental aspects of the mechanical deformation and structural properties of a crystal. In order to gain a deeper insight into the mechanical properties of the material, we calculate some polycrystalline elastic moduli such as the anisotropy factor A, Youngʼs modulus E, Poissonʼs ratio υ, and shear modulus G by employing the Voigt Reus Hill approach and expressions given in the followings:^[18–21] 1 2 3 4 where G_R is the representation of the Reussʼs shear modulus related to the lower bound values of G, G_V is the representation of the Voightʼs shear modulus related to the upper bound values of G, which are respectively expressed as 5 6 By using these relations, our calculated results are presented in Table 2. As Youngʼs modulus E describes the hardness of a material, meaning that when the value is higher, the material is considered to be stiffer and exhibits covalent bonding.^[22] The elastic anisotropy is another important physical quantity which tells about the structural stability and is decidedly coupled with the induction of the micro-cracks in the relevant material.^[23] If the system is completely isotropic, then gives a value of unity, any deviation from this unity highlights its degree of elastic anisotropy. The computed A for CaNiH₃ is found to be 1.428 (1.082) using the PBE-GGA (PW-LDA), which means that our compound is not elastically completely isotropic. Similarly, another important factor is the ratio B/G which classifies the materialʼs nature as ductile or brittle. Pughʼs criterion^[24] is used, i.e., if , the material will be ductile, otherwise it will be of the brittle nature. By employing this criterion, one can observe from Table 2 that CaNiH₃ is a ductile material (B/G=1.994). Another index of ductility is Cauchyʼs pressure which is obtained by taking the difference, . This difference serves as an indicator of ductility as well.^[25] If for Cauchyʼs pressure is found to be positive (negative), the material is predicted to be of the ductile (brittle) nature. As the calculated results for the Cauchyʼs pressure of CaNiH₃ are positive, hence showing clearly that CaNiH₃ is of ductile nature. Poissonʼs ratio provides more information about the characteristic nature of the bonding forces. It has already been standardized that the values of of 0.5 and 0.25 are upper and lower limits of the Poissonʼs ratio, respectively, for the central force of a solid.^[26] Following this, we see from Table 2 that the interactions in our investigated compound are central because the Poisson ratio is within the mentioned range.^[27] Figure 2 displays the pressure dependence of the elastic constants and bulk moduli of CaNiH₃, which shows a linear dependence for all the plotted curves in the considered range of pressure. Also, we see that C₁₁, C₁₂, C₄₄, and B₀ increase with increasing pressure, and the elastic constant C₁₁ is more sensitive to the change of pressure compared to the other elastic constants. To our knowledge, no experimental measurements or theoretical data for the elastic constants have been reported in the literature for this compound. This may give our results as a prediction for this hydride.

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	Fig. 2. (color online) Calculated pressure dependence of elastic constants C_ij and bulk modulus B₀ for CaNiH₃.

Table 2.

Calculated density ρ, anisotropy factor A, Youngʼs modulus E, Poissonʼs ratio υ, shear modulus G, (B/G) ratio, and Cauchyʼs pressure for CaNiH₃.

3.4. Debye temperature calculation

The role of the Debye temperature in the lattice vibration theory is the same as that of the Fermi temperature in the theory of electrons of metals since both represent a measure of the temperature to separate the low-temperature region (where quantum statistics is used) from the high temperature region (where classical statistics is found to be applicable). This is a very noteworthy parameter which is coupled to many materials’ thermal characteristics, in turn correlating to a lot of their physical properties, for instance, elastic constants, specific heat, and melting temperature. Therefore, the knowledge of this parameter is essential for suggesting a material suitability for the electronic devices.

To calculate the Debye temperature θ_D, a typical technique is derived from the data of elastic constants in which θ_D is estimated by averaging sound velocity v_m by employing the equation^[28] 7 where k_B, h, and ρ denote Boltzmannʼs constant, Plankʼs constant, and the density, respectively. N_A is Avogadroʼs number, n is the number of atoms in a molecule, and M is the molecular weight.

To calculate the average sound velocity, the following relation is used: 8 where v_t and v_l are the transverse and longitudinal sound velocities, respectively. These values are obtained using Navierʼs equation^[29] 9 10 Our calculated results of θ_D, (v_t, v_l, v_m), and ρ of CaNiH₃ employing relations (7)–(10) are tabulated in Table 3. It is found that the longitudinal velocity has a larger value as compared to the above-described velocities because the particle displacement is parallel to the direction of the wave propagation in longitudinal wave. Like the elastic constants, to our knowledge, no prediction or experimental investigation is found yet in the reported literature for comparison. It is expected that future experiments will confirm our reported calculations.

Table 3.

Calculated longitudinal v_l, transverse v_t, average elastic wave velocities v_m, and Debye temperature θ_D for CaNiH₃.

3.5. Electronic properties

The calculated band structure of the perovskite-type hydride CaNiH₃ along the higher symmetry directions in the Brillouin zone using (PBE-GGA) approach is shown in Fig. 3. The Fermi level is set at zero energy. From this figure, it can be seen that there are some bands that cross E_F, indicating the metallic chiastic of CaNiH₃. For obtaining deeper insight into the electronic structure of CaNiH₃, the total and partial densities of states (TDOS and PDOS) are displayed in Fig. 4. The lowest valence band in the energy range from −10.0 eV to −6.0 eV below E_F is found mainly due to the Ni-s and H-s states with a few contribution from the Ca-s states. The narrow band between −6.5 eV and −5.5 eV is the doubly degenerate level, which is mainly originated from the Ni-d_eg states and is in fact responsible for the bonding of Ni–H. The nonbinding, triplet degenerate Ni-d t2g states are also found to appear at −2.5 eV. At high energies, from −1.5 eV to 1.5 eV, the doubly degenerate state at the Γ point is an antibonding combination of Ni-d_eg and H-s states with Ca-d hybridization, resulting in the only half filling of the band. This half-filled band makes the CaNiH₃ a metallic conductor. The calculated DOS at E_F is around 0.865 states/eV/ atom. These states are mainly the d states of the Ni atoms. However, it is clear from Fig. 4 that there is very small contribution of Ca atomic states to the bands below the Fermi level. Overall the density of states profile and band structure plots are seen almost similar. Our obtained band structures are also found to be comparable with the already reported one by Sato et al.^[8] The authors also predicted that CaNiH₃ is characterized as a metallic conductor.

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	Fig. 3. (color online) Band structure alone high-symmetry directions in the Brillouin zone for the CaNiH₃ compound.

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	Fig. 4. (color online) Calculated total and partial densities of states for the CaNiH₃ compound.

3.6. Thermal properties

In order to determine the thermal effects at high pressure and high temperature, Gibbs computational code based on the quasi-harmonic Debye model is used.^[30] In this method, Gibbs function in the non-equilibrium form is described in the following way: 11 where is the non-equilibrium Gibbs function, E(V) is the total energy/unit cell, the product PV stands for the constant hydrostatic pressure condition, and vibrational Helmholtz free energy A_vib and is written as^[31,32] 12 Here, is the Debye integral for an isotropic solid, and n is the number of atoms/formula unit. The expression for θ_D is given as^[31] 13 where M is the molecular mass per unit cell and B_s is the adiabatic bulk modulus in the Debye model, which is approximated by the static compressibility as follows:^[30] 14 The comprehensive description of the function f(σ) can be seen in Refs. [33] and [34]; σ is the Poisson ratio which takes the value 0.25.^[35] The Gibbs function , which is a function of (V,P,T), for non equilibrium conditions is minimized with regard to volume V as 15 From the solution of Eq. (15), one can derive the corresponding thermal equation of state V(P,T). From this, the heat capacity (C_V), isothermal bulk modulus (B_T), and the coefficients of the thermal expansion (α) can be obtained as^[36] 16 17 18 where γ is the Grüneisen parameter, which is defined as 19 In the present study, the calculations of the thermal properties are done over a temperature range from 0 to 600 K. It is found that the quasi-harmonic model is most likely applicable in view of the fact that the temperature we considered is far away from the melting temperature. The pressure effects are investigated over a range of 0–6 GPa. Figure 5 presents the lattice parameters of the CaNiH₃-perovskite under different pressures at different temperature. One can easily note that the lattice parameters increase with increasing temperature at a given pressure, however, the increasing rate is very modest. The lattice constants dramatically decrease with increasing pressure at a given temperature. The temperature effect on the bulk modulus is shown in Fig. 6. It can be seen from the figure that the obtained bulk moduli are almost constant from 0 to 100 K, but decrease linearly above 100 K. It is also found that the compressibility decreases with increasing pressure at a given temperature and increases with increasing temperature at a given pressure owing to the fact that the effect of decreasing temperature is same as that of increasing pressure on the material. The specific heat is another important thermodynamic property of the material which measures the loss ability or heat retention. Moreover, it provides the insight into the vibrational and many other obligatory properties of a substance. We plot the heat capacities C_V and C_P versus temperature at various pressures in Figs. 7(a) and 7(b). As it can be seen in these figures that at low-temperature ( ), C_V and C_P increase more rapidly with increasing temperature and then C_V becomes proportional to .^[37] Comparing for different pressures, one can deduce that the influence of the pressure on is significant at low temperature ( K), whereas at high temperature, the effect of the pressure on the variation of with temperature becomes smaller and the heat capacity at constant volume calculated at each pressure tends to approach the Petit and Dulong limit ( similar to most of solids.^[38] At high temperature, continues to increase linearly. But, for the intermediate temperature range, it is found that the specific heat capacity is mainly governed by the atomic vibrations. The calculated C_V and C_P at room temperature (300 K) and zero pressure are and , respectively.

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	Fig. 5. (color online) Variation of the lattice constant as a function of temperature at different pressures for CaNiH₃.

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	Fig. 6. (color online) Variation of the bulk modulus as a function of temperature at different pressures for CaNiH₃.

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	Fig. 7. (color online) Variation of the heat capacities (a) C_V and (b) versus temperature at various pressures.

The variation of the Debye temperature with respect to the pressure is presented in Fig. 8. From the figure, one can easily note that θ_D is almost constant within the temperature range from 0 to 100 K and starts decreasing linearly with the increase of the temperature above 100 K. We also note that with the constant temperature, θ_D approximately increases linearly with respect to the applied pressure. Thus the temperature/pressure dependence of θ_D clearly shows that the atomic thermal vibrational frequency of the CaNiH₃ hydride varies with the temperature and pressure. As it is recognized already that the harder materials demonstrate higher θ_D. It is obvious from Fig. 8 that the θ_D with regard to the pressure confirms the positive trend. From our calculations, we find that the θ_D at room temperature and zero pressure is 574.65 K. We also find that our obtained results are in nice agreement with the obtained results by following the relations of the sound velocities, i.e., 562.55 K. Our work regarding C_V and θ_D is the first attempt about this material as there is no study found in the literature. Hence our work might be the first attempt in this direction.

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	Fig. 8. (color online) Variation of the Debye temperature θ_D with the temperature at different pressures for CaNiH₃.

4. Conclusion

The calculations of the structural, elastic, thermal, and electronic properties of the CaNiH₃ ternary compound were carried out by using ab initio FP-LAPW+lo computational method at the level of PW-LDA and PBE-GGA exchange–correlation energy functional. We found that the obtained results of the lattice constants, as well as bulk modulus, were in a nice agreement with the available data in the literature. Also, we have computed elastic constants C₁₁, C₁₂, and C₄₄ to determine the shear modulus, anisotropy factor, and Debye temperature. It was found that our computed elastic constants of CaNiH₃ adequately followed the stability criteria whereas its electronic band structure and DOS profile demonstrated its metallic nature. To understand the dependence of the lattice parameters, bulk modulus, Debye temperature, and specific heat capacity on the temperature and pressure, the quasi-harmonic Debye model was employed. It was deduced that our predictions concerning specific heat C_V of the CaNiH₃ hydride were closely following the Dulong–Petit law, showing that our results were in line with many other solids at high temperature. Hence, our first-principles DFT calculations performed in this study can be a very useful as a guide to complement future experiments.

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