Microsoft Word - ETASR_V12_N1_pp8151-8156 Engineering, Technology & Applied Science Research Vol. 12, No. 1, 2022, 8151-8156 8151 www.etasr.com Iliass et al.: DFT Investigation of the Structual and Optoelectronic Properties of Alkali Metal Hydrides … DFT Investigation of the Structual and Optoelectronic Properties of Alkali Metal Hydrides MH (M=Li, Na) Taieb Iliass Materials Science and Informatics Laboratory Faculty of Science, University of Djelfa Djelfa, Algeria iliasstaieb@yahoo.com Hamza Ziani Materials Science and Informatics Laboratory Faculty of Science, University of Djelfa Djelfa, Algeria hamza_ziani@yahoo.com Ahmed Gueddim Materials Science and Informatics Laboratory Faculty of Science, University of Djelfa Djelfa, Algeria ahmed_gueddim@yahoo.fr A. Djamel Guibadj Laboratory of Physical Chemistry of Materials Faculty of Science, University of Laghouat Laghouat, Algeria d.guibadj@gmail.com Abstract-This paper presents ab initio calculations within the Density Functional Theory (DFT) for the structural and optoelectronic properties of the alkali metal hydrides LiH and NaH in rocksalt structure (B1). This study used the Generalized Gradient Approximation (GGA) of Wu-Cohen to consider the electronic exchange and correlation interactions. In addition, the Tran-Blaha modified Becke-Johnson exchange potential was used with the GGA approach (GGA-TBmBJ) to calculate the band structure with high accuracy. The structural properties, namely the lattice parameter, the bulk modulus, and the pressure derivative of the bulk modulus were determined and found to be generally in good agreement with other research findings. Furthermore, the energy band gaps, the Density Of States (DOS), the static and high-frequency dielectric constant, along the refractive index were addressed and analyzed. These results could be useful for hydrogen storage purposes. Keywords-Hydrogen storage; LiH; NaH; ab initio; mBJ-GGA I. INTRODUCTION The energy transition is necessary in order to meet the increasing energy needs and cope with global warming. The main drivers for this transition are the adoption of responsible consumer practices and the increased use of renewable sources of energy. This transition also requires efficient processes for production, conversion, storage, and transport of energy. Many scientific and technological challenges exist in each of those axes. As the problem of suitable materials is ubiquitous, materials science is at the heart of this research. The challenge is to obtain and optimize materials having specific properties to fulfill the requirements of renewable energy. Hydrogen is a transportable, storable, and convertible energy medium and has great potential to become the ultimate solution that combines energy security, resource availability, and environmental compatibility. However, the greatest challenge in the development of hydrogen-based technologies is how to store hydrogen safely, effectively, and economically [1-5]. Depending on the physical state of hydrogen, three different routes are currently used for its storage: compressed gas, liquid, and solid-state. Hydrogen stored as a solid-state material has potential advantages in terms of volumetric density and safety, compared to compressed gas or liquid [6- 11]. In the case of solid-state, the bonds between hydrogen and the host material can be of different kinds and strengths. Both van der Waals weak and chemisorptive strong bonds can be involved [11]. It is possible to increase the density of hydrogen, as it is packed with H-H distances up to 170kg/m 3 in many hydride-type materials. This value is higher than the density of hydrogen in a liquid state [12]. Numerous studies have been conducted to determine and design the most suitable materials with convenient gravimetric and volumetric densities for hydrogen storage. These materials span a large class, from conventional metal hydrides to complex hydrides, microporous materials, and clathrate hydrates. This study addresses some fundamental properties of LiH and NaH using the first principles calculations to utilize the Density Functional Theory (DFT). Such calculations are of great interest before the synthesis procedure, which is a very time-consuming effort. The structural properties along with their electronic and optical features are explored and analyzed for the materials under load in the rock-salt (B1) structure. The comparison with experimental and theoretical data, when possible, shows satisfactory agreement in general. II. COMPUTATIONAL METHODOLOGY This study used the Full Potential Linearized Augmented Plane Wave (FP-LAPW) method, based on the DFT [13] that constitutes the core of the WIEN2k code [14]. Exchange- correlation energy was calculated using the WC-GGA [15] when dealing with structural properties. The exchange- correlation functional mBJ [16] was applied to determine the electronic and other optical characteristics. In the FP-LAPW Corresponding author: Ahmed Gueddim Engineering, Technology & Applied Science Research Vol. 12, No. 1, 2022, 8151-8156 8152 www.etasr.com Iliass et al.: DFT Investigation of the Structual and Optoelectronic Properties of Alkali Metal Hydrides … method, the wave function and the potential are developed as sums of spherical harmonic functions inside non-overlapping spheres, surrounding the atomic sites (muffin-tin spheres), and a set of plane waves in the interstitial region. A plane wave cut- off of RMT.kmax=7 (where RMT is the smallest muffin-tin radius in the unit cell) was used. RMT’s were chosen to be 1.7, 2.1, and 2.5a.u. for H, Li, and Na, respectively. The k-sampling over the Brillouin zone was performed up to a 13×13×13 Monkorst- Pack [17-20] mesh for both considered materials. The number of k-points and the plane wave cut-off energy varied in such a manner as to obtain total energy convergence. The convergence of these self-consistent calculations was considered to be obtained within an error of 10 −5 Ry on the total energy of the crystals studied. III. RESULTS AND DISCUSSION The total energy was calculated from the WC-GGA approach as a function of the volume of LiH and NaH in the rocksalt structure. At first, the total energy for some selected lattice parameter values was calculated. The results obtained were then written according to Murnaghan’s equation of state [21]. This allowed determining the equilibrium lattice parameter a0, the zero pressure bulk modulus B0, and the first- order pressure derivative of the bulk modulus B ́ for the ground-state. These results are summarized in Table I with experimental and theoretical data from other researches for comparison. The WC-GGA lattice parameter in this study is generally closer to the experiment than those of the GGA or LDA approaches [27-29]. The a0, calculated for both LiH and NaH from WC-GGA, agrees quite well with those reported in [22, 23]. The same remark can be drawn for the bulk modulus B0, which agrees within a few percent with other experimental or theoretical values [22, 24-26]. TABLE I. a0, B0, AND B' FOR LiH AND NaH IN B1 STRUCTURE USING GGA AND WC-GGA ALONG WITH THE VALUES REPORTED IN THE LITERATURE. Material ��(Å) �� (GPa) �′ LiH 3.9934 a 4.0153 b 4.012 c 3.92 d 38.1840 a 41.1635 b 36.228 c 36.60 e 34.7 f 3.9913 a 3.0976 b 3.51 c 3.40 e NaH 4.8051 a 4.8347 b 4.833 c 4.775 d 25.9068 a 23.0855 b 23.546 c 19.40 f 22.9 g 4.1001 a 6.560 b 3.90 c 4.40 f a. Present calculation using WC-GGA, b. Present calculation using GGA, c. [22], d. [23], e. [24, f. Experimental value quoted in [25], g. [26] The formation energy is an important thermodynamic quantity that permits one to characterize and classify hydrogen storage materials. Formation energy is defined as the difference between the sum of the total energies of the products and the reactants: ∆� � ∑ � � ����� �� � ∑ � ����� �� �� (1) The formation of MH (M=Li, Na) materials from their constituting elements is given as: � � � → �� (2) The formation energy can be written as: ∆� � ������� � ������ � ������ (3) The total energies of LiH, NaH, Li, Na, and H were calculated. The formation energies of LiH and NaH were found to be -88.91kJ.molH2 and -109.054kJ.molH2, respectively. The desorption temperature of hydrides was estimated using the standard Gibbs energy: �� � �� � �� (4) where ∆H and ∆S are the enthalpy of formation and the standard entropy of the reaction respectively. At equilibrium, the standard Gibbs energy ∆G is zero. Therefore, the desorption temperature can be expressed as: � � � !"!# (5) The calculated desorption temperature was 680.33K for LiH and 834.38K for NaH. The gravimetric hydrogen storage capacity can be determined as: $%� % � ' ( ) *+ ,) ,)-./0()*+,) 1 1004 (6) where H/M is the hydrogen to material atom ratio, MH is the molar mass of H, and MHost is the molar mass of the host material. The hydrogen storage capacities calculated for LiH and NaH were 22.5% and 8.06%, respectively. (a) (b) Fig. 1. Electron band structure calculated using TB-mBJ-GGA along high symmetry directions for (a) LiH and (b) NaH. Engineering, Technology & Applied Science Research Vol. 12, No. 1, 2022, 8151-8156 8153 www.etasr.com Iliass et al.: DFT Investigation of the Structual and Optoelectronic Properties of Alkali Metal Hydrides … The electronic and optical properties of the materials are classically described by their electronic band structure [30-33]. Accurate knowledge of the band parameters of a given material provides precious information regarding its synthesis and devices fabrication [34-37]. The results of using the GGA- TBmBJ approach to compute the electronic band structure of rocksalt LiH and NaH are plotted in Figure 1. It should be noted that, from a qualitative point of view, the same picture is observed for all the reported band structures. The Fermi level energy does not cross any energy bands for all questioned crystal materials. Therefore, LiH and NaH in the rocksalt structure can be considered respectively as semiconductor and insulating materials. According to Figure 1, the valence band maxima and the conduction band minima are located at the same high symmetry point X in the Brillouin zone. The band gaps of these materials are direct in nature, agreeing with the results of [22]. The fundamental difference between the band structures arises from the magnitude of their fundamental energy band gap, which differs from one band structure to another. The calculated fundamental direct band gap (X-X) for the rocksalt LiH and NaH were 3.05 and 3.65eV respectively. (a) (b) Fig. 2. Density of states (DOS) calculated using TB-mBJ-GGA for (a) LiH and (b) NaH. The properties of semiconductors can be related to the electron configuration shown by the molecules. The Densities Of States (DOS), total and projected, were computed for the rocksalt LiH and NaH using the TB-mBJ approach to show how the electrons are distributed on different orbitals. The results are shown in Figure 2. An inspection of LiH (Figure 2(a)) shows that the first region of the DOS is the most tightly bound energy band. The contribution of the Li-s electrons is predominant for the energy bands near the Fermi level of the LiH crystal. Hence, the Li-s electrons are useful for the conductibility of the crystal of interest. The DOS at these regions consist essentially of Li-s and Li-p states. The contribution of the H-s states was remarkably weak. Figure 2a also shows that the bonding peaks ranged from about -5 to 0eV. These peaks were mainly formed by the Li-s state. For NaH (Figure 2b), it is observed that the intensity of the H-s orbitals in the valence band constitutes the dominant contribution to the DOS. The Na-p and Na-s states have a minor contribution to the DOS compared to the H-s orbitals. The bonding peaks ranged from about -3.75 to 0eV. Moreover, the optical properties, such as the dielectric function, were examined. The computed optical response functions, real ε1(Ε) and imaginary ε2(Ε), for LiH and NaH are displayed in Figures 3 and 4 respectively, where E is the photon energy. The main peak of the real parts of LiH and NaH occurs around E=2.94eV and E=4.58eV respectively. Fig. 3. Real part of the dielectric function calculated using TB-mBJ-GGA. Fig. 4. Imaginary part of the dielectric function calculated using TB-mBJ- GGA. Based on the optical transition mechanisms, the optical spectrum of a given crystal is usually classified into several photon energy regions [38]. In general, three spectral regions are distinguished. The first one is known as the reststrahlen region and is characterized by the interactions between the radiation field and the fundamental lattice vibrations [38]. For very low energies, the real part of the dielectric function tends to the static or low-energy dielectric constant ε0. The ε0 for LiH and NaH materials were determined as: Engineering, Technology & Applied Science Research Vol. 12, No. 1, 2022, 8151-8156 8154 www.etasr.com Iliass et al.: DFT Investigation of the Structual and Optoelectronic Properties of Alkali Metal Hydrides … 56�78�� � 4.55 (7) 56�<��� � 3.21 (8) Regarding the ε0 of LiH, this result is different from the quoted in [39]. To the best of our knowledge, no data regarding ε0 for NaH has been reported so far. Thus, this result could serve as a reference. The optical constant that relates the so- called reststrahlen region to the near-infrared region is commonly known as the high-frequency dielectric constant ε∞. For these materials, the calculations gave: 5?�78�� � 7.84 (9) 5?�<��� � 10.82 (10) The calculated ε∞ for LiH shows reasonable agreement with the one reported in [34]. For NaH, the calculation in [40] gave a value of 3.71, which is too low compared to this result. The general shape of ε1 was expected for a harmonic oscillator with resonant frequencies of about 8.39 and 5.71eV for LiH and NaH, respectively. It is generally accepted that the resonance frequency is a fundamental property of a given material. This quantity allows the expression of the average energy that separates the levels of bonding and anti-bonding [30]. The absorption for the imaginary part of the dielectric function starts at about 2.04 and 3.09eV for LiH and NaH, respectively. Similar behavior was reported in [41, 42] for ZnTe1-xOx alloys. Knowledge of the refractive index of semiconductors in the energy range below or near the fundamental absorption edge is mostly interesting in device design [43-48]. This refractive device (n) can be easily derived from the dielectric function ε(Ε). The n values obtained for LiH and NaH were: ��78�� � 2.8 (11) ��<��� � 3.29 (12) The n value for LiH is in reasonable agreement with the value of 1.47 reported in [49]. The calculated spectral dependence of n(E) for LiH and NaH is shown in Figure 5. Fig. 5. Refractive index calculated using TB-mBJ-GGA for LiH and NaH. From this spectrum, it can be noted that clear peaks are present. These peaks are due to the excitonic transitions at the E0 edges. Excitonic effects are believed to be responsible for the enhancement of the oscillator strength at the critical points M0 and M1 [50]. Since the total strength of the oscillator is proportional to the number of valence electrons, it should be ''conserved'' in some way. This means that as the oscillator strength at the critical points M0 and M1 is enhanced due to excitonic interactions, some losses occur elsewhere to achieve strength conservation. The strongest peaks in the n(E) spectra can be explained as the result of the 2D exciton transition (E1). IV. 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