AB INITIO MODELING OF RAMAN AND INFRARED SPECTRA OF CALCITE
N.V. Kalinin1, V.A. Saleev1 1Samara National Research University, Samara, Russia
Abstract
Calcite is the most thermodynamically stable polymorphic phase of the CaCO3 crystal. It is widely used in modern optical instruments operating in the infrared and visible wavelengths of electromagnetic radiation. In particular, due to its anisotropic properties, calcite is used in polarization optics devices. Ab initio quantum mechanical modeling of the Raman and infrared spectra of calcite makes it possible to better understand the structure and nature of the chemical bonds of the compound, and find the optimal conditions for the effective use of unique properties of calcite in photonics tools. The calculations are performed within the framework of the density functional theory in the CRYSTAL program, using the "hybrid" B3LYP functional and the all-electronic bases of the STO-6G, PO-TZVP and BSD atomic orbitals of the Gaussian type. The obtained results for the elastic constants, Raman and infrared spectra of calcite agree satisfactorily with the available experimental data for the basic sets of POB-TZVP and BSD.
Key words: photonics; calcite; IR spectrum; Raman spectrum; ab initio modeling; density functional theory; hybrid functional.
Citation: Kalinin NV, Saleev VA. Ab initio modeling of Raman and infrared spectra of calcite. Computer Optics 2018; 42(2): 263-266. DOI: 10.18287/2412-6179-2018-42-2-263-266.
Acknowledgments: The work was partially funded by the Ministry of Education and Science of Russia under Competitiveness Enhancement Program of Samara University for 2013-2020, project 3.5093.2017/8.9.
Introduction
The physical properties of the most thermodynamical-ly stable polymorphic phase of the CaCO3 crystal, calcite, have been extensively studied experimentally and can be used to test modern methods of quantum-mechanical (ab initio) modeling based on the equations of the density functional theory (DFT) [1]. Calcite is widely used in modern optical instruments operating in the infrared and visible wavelengths of electromagnetic radiation. First of all, due to its anisotropic properties, calcite is used in devices of polarization optics. In this paper, we simulate the Raman and infrared (IR) spectra of calcite in an approach based on the semi-classical theory of the Drude-Lorentz scattering, for electromagnetic radiation with a wavelength significantly exceeding the dimensions of the atom [2]. In this approach, the crystal is considered as an ensemble of effective oscillators characterized by a set of natural vibration frequencies and "oscillator forces". To find the parameters of the model, quantum mechanical methods are used to calculate the spectrum of the elastic vibrations of the crystal and the complex dielectric tensor, which is written in the diagonalized form as the sum of two terms
ea (V) = ^op,.«+ X
f V
J p,ll p
22 VP -V - lVY p
(1)
where the double index ii defines the direction of polarization, eopt - is the optical (high-frequency) dielectric tensor, Vp, fp u Yp are the frequencies of the transverse optical oscillations, the oscillator strengths and damping factors for the mode of oscillation p, respectively. The optical dielectric tensor is calculated in the model of quasi-free electrons and the Hartree-Fock or Kohn-Sham approaches [3], as an electron density response to the applied external field, using perturbation
theory methods. The calculation of the natural vibration frequencies Vp (eigenfrequencies) is performed in the harmonic approximation. For this, the matrix H of the second derivatives of the total energy is calculated from the Cartesian coordinates of the atoms in the relaxed unit cell in which the atoms are in equilibrium. The oscillation frequencies are found as eigenvalues of the Hessian matrix at the T-point:
i A
ij' _
H al.bj
1
4MaMb
d2 E du du
bj
(2)
where E is the total energy, u« is the i-th Cartesian coordinate of the a atom.
Methods for calculating Raman and IR spectra, in the above approximation, are described in [4, 5] and are used by us as they are implemented in the CRYSTAL14 software package [6]. In particular, the classical absorption coefficient averaged over the polarization directions is expressed in terms of the imaginary part of the complex refractive index n* (v) = ^/eii (v) :
I (v) = 3 X 0Im M (V)] ■
(3)
Computational Methods The calculation of the energy of the unit cell of the crystal and all its derivatives in the DFT is performed using all-electronic basis sets of Gaussian type and the hybrid functional B3LYB [6], in the program complex CRYSTAL14 [13]. The choice of this software package is because it has proved to be an effective software product for calculating the structural and frequency properties of ionic crystalline compounds [7]. The choice of the hybrid functional B3LYP, in which the exchange and correlation interactions are described taking into account both
p
the Hartree-Fock exchange and the Kohn-Sham correlation contributions, is due to the large positive experience of its use in calculations of organo-inorganic dielectric structures. In order to take into account the dependence of the calculation results on the choice of the all-electronic basis, we perform calculations with three basic sets: the minimal STO-6G Pople's base set [8], the basic set with polarization properties - POB-TZVP [9] and the adapted basic set BSD [10]. The first two sets are optimized for the calculation of individual molecules and one-component crystalline structures, respectively. The BSD basic set is a modification of the STO-6G basic set and is optimized for the calculation of compounds containing CO complexes. In the CRYSTAL14 package, the level of accuracy of calculating the energies of the Coulomb and Hartree - Fock exchanges is controlled by a set of TOLIN-TEG parameters, which were chosen as {8, 8, 8, 8, 18}. The accuracy of calculating the self-consistent value of the energy of a unit cell was assumed 10 9 Hartree. The number of basis vectors in the irreducible Brillouin zone is given by the parameter IS = 8, which corresponds to 65 independent k-vectors. The relaxation of cell parameters and atomic positions to equilibrium values was carried out until the effective pressure became less than 0.02 GPa.
Results
The first step is to optimize the geometry of the cell and the position of the atoms for a different choice of basic sets. Table 1 shows the values of the parameters of the crystallographic cell of calcite (hexagonal symmetry group N-167, R3c) for three different basic sets that are compared with the experimental data obtained at T = 80 K. The values obtained for the relaxed values of the lattice parameters and c do not differ from the experimental values by more than 1.5%, which is considered a good approximation. The STO-6G basic set reproduces the cal-cite crystal density well, but the density values obtained with the other two basic sets are also quite satisfactory.
Table 1. Parameters of a crystalline calcite cell
Basic set STO-6G POB-TZVP BSD Experiment, [4]
a, A 5.03 5.06 5.05 4.99
c, A 16.69 17.32 17.28 17.06
p, g/cm3 2.72 2.59 2.61 2.71
The standard test of checking the mechanical stability of a structure is to calculate the matrix of its elastic constants and check for the positivity of its eigenvalues. Table 2 contains the non-zero elastic constants of the CaCO3 crystal, as well as the calculated and experimentally measured values of the modulus of compression (K), the shear modulus (G) and the linear deformation modulus or Young's modulus (E). The elastic moduli are calculated from the values of the elastic constants, as the average of the quantities obtained from the formulas of Reuss and Voigt (Hill's notation) [11]. Also in Table 2 are the calculated values of the Poisson's ratio v. It can be seen that the basic sets of POB-TZVP and BSD describe the experimental data much better than the minimum set of STO-6G. Another important characteristic of the elastic prop-
erties of a crystal is the dispersion spectrum of phonons and the density of states of the phonon spectrum, which are shown in Fig. 1, the calculation is performed with a basic set of BSD for the supercell {2, 2, 2}.
Table 2. Non-zero elastic constants of calcite
Constants Cab, and elastic module, GPa Experiment, [12] Basic set
STO-6G POB-TZVP BSD
C11 146.0 208.5 151.7 160.2
C12 59.7 100.2 53.7 59.3
C13 50.8 90.4 52.6 55.6
C14 -20.5 -36.5 -18.3 -17.9
C33 85.0 108.9 81.6 91.6
C44 34.0 40.5 34.9 36.1
Eh 88.2 85.5 90.2 96.0
Gh 32.0 31.1 34.7 36.9
Kh 76.8 113.2 74.3 80.3
V 0.31 0.37 0.30 0.30
v, 1/cm 1600 ~
Band structure
Density of states
T FA r L T
Fig. 1. The phonon spectrum of calcite along the path of high symmetry in the space of the reciprocal lattice
The spectrum observed experimentally at T = 80 K [4] and calculated Raman shifts for different choice of basis sets is collected in Table 3, and the Raman spectrum of calcite is shown in Fig. 2. In calculating the complex dielectric tensor £u (v), using the formula (1), the following values of the optical dielectric tensor obtained in the approximation of quasi-free electrons were used: for the base set STO-6G - e« = £yy = 2.43 and = 1.61; for the basis of POB-TZVP - e« = eyy = 2.45 and eH = 1.88; for the basis BSD - exx = eyy = 2.51 and ezz = 1.97. The results of the calculations demonstrate good agreement with experiment when choosing a basic set of BSD, for which the difference between the calculated and experimental values for four frequencies out of five is from 1 to 6 cm -1. A significant difference (about 35 cm-1) is observed only for the highest frequency.
Table 3. Spectrum of Raman frequencies
Raman frequencies Basic set Experiment, T=80 K
STO-6G POB-TZVP BSD
v, cm-1(Eg) 174.0 170.1 158.1 159.0
v, cm-1(Eg) 394.7 364.2 286.5 286.9
v, cm-1(Eg) 699.3 669.1 709.8 712.4
v,cm-1(A1g) 1115.5 917.4 1094.1 1087.1
v, cm-1(Eg) 1522.5 1167.3 1471.2 1436.6
Intensity
80 r
60
40
20
0
Li
i
i
200 600 1000 1400 \,crrr' Fig. 2. Raman spectrum of calcite, black lines - calculation, dashed vertical lines - experiment. Intensity is presented in arbitrary units
The Figures 3 and 4 show the results of calculations with the basic set of BSD for the real (n) and imaginary (k) parts of the complex refractive index n*, which characterize the scattering and absorption properties of the calcite crystal by electromagnetic radiation in the infrared wavelength range. The refractive index n depends on the polarization of the radiation and the directions of the crystallographic axes of the crystal. In the static limit (X ^ <»), its values for mutually perpendicular directions are 2.69 and 2.43 (calculation with the BSD basis), and in the high-frequency (optical) limit - 1.58 and 1.40, which is reasonably consistent with the experimental values for a wavelength of 633 nm -1.58 and 1.49. Calculations show that the imaginary part of the refractive index k is approximately isotropic and the absorption is independent of the polarization of the IR radiation (see Figure 4) and it is characterized by five narrow absorption bands with significantly different intensities in the range from 6 to 100 ^m.
0 10 100 X,\im
Fig. 3. Calcite refractive index n=Re[n*], as a function of wavelength, for rays parallel to the crystallographic axes a (b) and c of the calcite lattice, respectively
Calcite is a pronounced dielectric with a wide band gap between valence energy levels and the conduction band. Our calculations give the following values for the width of the indirect bandgap: the basis of STO-6G - 5.87 eV, the POB-TZVP basis - 7.62 eV and the BSD basis - 7.69 eV. Thus, the edge of the optical absorption zone begins in the region of the ultraviolet spectrum and the calcite is trans-
parent in the visible part of the spectrum and in the region of the peak of standard solar radiation (1.5 - 3.5 eV).
0 10 100 X,\im
Fig. 4. Coefficient of extinction of calcite k=Im[n*], as a function of wavelength
Conclusion
Modern ab initio methods of quantum mechanical calculations make it possible to describe and make predictions for Raman and infrared spectra of scattering and absorption of electromagnetic radiation of crystal structures. The calculations performed in the CRYSTAL14 software for calcite crystals (CaCÜ3) are in good agreement with the available experimental data, which confirms the correctness of the theoretical approach based on the density functional theory [1] and its great predictive capabilities.
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Authors' information
Vladimir Anatolievich Saleev (b. 1959) graduated from Kuibyshev State University (presently, Samara National Research University) in 1981, majoring in Theoretical Physics. Currently he works as Professor at the Samara National Research University. Research interests are quantum mechanics, quantum field theory, theoretical materials science and high energy physics. E-mail: [email protected] .
Nikita Victorovich Kalinin (b. 1995) graduate student of the Samara National Research University. Research interest is theoretical materials science and photonics. E-mail: [email protected] .
Code of State Categories Scientific and Technical Information (in Russian - GRNTI): 29.31.21. Received October 12, 2017. The final version - March 22, 2018.