A Lattice Dynamical Investigation of Raman and Infrared Wavenumbers of Mn2SiO4

DOI : 10.17577/IJERTCONV5IS05037

Download Full-Text PDF Cite this Publication

Text Only Version

A Lattice Dynamical Investigation of Raman and Infrared Wavenumbers of Mn2SiO4

Harleen Kaur

Dept. of Applied Sciences

Baba Banda Singh Bahadur Engineering College Fatehgarh Sahib, India

M. M. Sinha

Dept. of Physics

Sant Longowal Institute of Engineering & Technology Longowal, Sangrur, India

Abstract Wilson's GF matrix method has been applied for the investigation of optical phonons of Mn2SiO4 in orthorhombic phase having space group Pbnm using normal coordinate analysis. The calculation of zone center phonons have been made with fifteen stretching and ten bending force constants. The calculated values of Raman and infrared wavenumbers are in good agreement with the experimental values. The contribution of each force constant towards the zone centre phonons has been determined in terms of potential energy distribution.

Keywords Phonon spectra; lattice dynamics; force constant; potential energy distribution.

  1. INTRODUCTION

    Olivine, (Mg,Fe)2SiO4, is the major rock-forming mineral in the Earths upper mantle [1]. The family of olivine compounds, including forsterite (Mg2SiO4), fayalite (Fe2SiO4), tephroite (Mn2SiO4) and solid solutions between them, play a significant role in geosciences since olivines are the most common silicate phases in the Earth's mantle. Manganese orthosilicate, Mn2SiO4, the mineral tephroite, has been the subject of structural, crystal, chemical and thermodynamical study because of its petrological and geophysical importance [2]. Apart from its importance in Earth sciences, this family of olivines is potentially significant from technological point of view [3-4]. Silicate olivines show predominant occurence in igneous rock and have been used as an important composition in some refractory materials, grit blasting materials, ceramic pigments, additives in cement concrete, flux and slag conditioner in the steel industry [5-6], and so on.

    The study of phonon properties of these minerals is crucial for understanding the phenomenon of phase transition in such compounds. The complete information of the macroscopic behavior of the minerals can be best obtained from a detailed knowledge of microscopic nature and this relation is best made via their vibrational spectra. However, the experimental task required for studying the lattice dynamical behavior and properties of minerals is exigent because of the technical difficulties involved in reproducing the temperature and pressure conditions that are relevant to the Earths interior and in carrying out controlled experiments at such conditions. Therefore, the theoretical prediction of vibrational properties through accurate modeling is the only feasible solution. It is well known that many interatomic force dependent properties of solids can be described very

    successfully through harmonic models. Hence, in the present work, the lattice dynamical investigation of Mn2SiO4 olivine has been undertaken within the harmonic approximation.

    Previous studies reveal that Mg2SiO4 and Fe2SiO4 olivines have been a subject of thorough study to investigate the lattice dynamical properties both experimentally and theoretically [7-9], but few studies have been conducted to investigate the spectral activity in Mn2SiO4. However, none of the observations [10-11] could assign all the observed Raman and infrared modes in Mn2SiO4. Also to our knowledge, no theoretical calculation of optical phonons has been made in the orthorhombic phase of Mn2SiO4. Hence, in this paper a short range force constant model has been applied to investigate the optical phonons using normal coordinate analysis involving fifteen stretching and ten bending force constants. The theoretically obtained wavenumbers are in very good agreement with the experimental ones. Also, an effort is also made to assign experimental wavenumbers to their respective optical phonon modes. The potential energy distribution (PED) has also been investigated for determining the significance of contribution from each force constant towards the Raman and infrared wavenumbers.

  2. THEORY

    Mn2SiO4, the mineral tephroite, crystallizes in the orthorhombic olivine structure with space group Pbnm (no

    62) and D2h symmetry with four formula units. The structure is composed of an almost hexagonally close packed array of oxygen ions. One eighth of the tetrahedral sites are occupied by silicon ions and one half of the octahedral positions are filled with manganese ions. The Mn octahedra have common edges and form chains along the c-axis. Mn ions occupy two crystallographically non-equivalent octahedral positions with different site symmetries, M1 and M2 (as given in Fig 1) with M1 having 4a site and M2 occupying 4c site. The oxygen ions occupy three distinct positions i.e. O1, O2 and O3. Si, O1and O2 reside at 4c and O3 ions occupy 8d site. The crystal structure consists of SiO4 tetrahedra linked by the divalent manganese cations in six fold oxygen anion coordination. Thus there are twenty eight atoms in primitive cell resulting in eighty four vibrational modes. The detailed analysis of total number of modes at zone centre (k=0) is:

    total= 11Ag+11B1g+7B2g+7B3g+10Au+10B1u+14B2u+14B3u

    where B1u+B2u+B3u are acoustical modes, 11Ag, 11B1g, 7B2g and 7B3g are Raman active, 9B1u, 13B2u and 13B3u are infrared active and 10Au are inactive modes.

    Wilsons GF matrix method [12] has been employed to calculate the Raman and infrared wavenumbers by using normal coordinate analysis. In this method the concept of internal coordinates is being introduced which makes the problem more logical. These internal coordinates includes the parameters like bond distances and angles or interatomic distances. The zone centre modes are determined in terms of kinetic and potential energies of the system. The Kinetic energy T is dependent on geometrical arrangement of the atoms and their masses mij where as the potential energy V which originate due to interactions within the molecule is defined in terms of force constants Fij .

    36 36

    The present study includes fifteen stretching Ki and and ten bending force constants Hi to formulate F matrix. The short range forces are significant upto certain neighbors and their magnitude generally decreases after the second neighbor interaction. The reason for inclusion of bending forces in our calculations is that the stretching forces only are not sufficient to explain transverse vibrations. Short range stretching forces between nearest neighbors Si-O, Mn-O, O- O and bending forces between O-Mn-O and O-Si-O are used in the present analysis. The input parameters used for the study are masses of the atoms, unit cell dimensions [13], symmetry coordinates and available Raman and infrared frequencies [11].

  3. RESULTS AND DISCUSSION

    The force constants as given in Table I have been optimized and empirically scaled so as to make the

    = 1

    2

    (1)

    vibrational wavenumbers in good agreement with the observed Raman and infrared numbers.

    =1 =1

    = 1

    Mn1-O2

    Force constant

    Between atoms

    Coordination Number

    Distance (Ã…)/

    Angle (degree)

    Force

    constant value

    K1

    Si-O1

    4

    1.619

    3.812

    K2

    Si-O3

    8

    1.639

    3.466

    K3

    Si-O2

    4

    1.657

    3.388

    K4

    8

    2.167

    0.474

    K5

    Mn1-O1

    8

    2.200

    0.414

    K6

    Mn1-O3

    8

    2.249

    0.328

    K7

    Mn2-O2

    4

    2.139

    0.522

    K8

    Mn2-O3

    8

    2.154

    0.354

    K9

    Mn2-O1

    4

    2.278

    0.311

    K10

    O2-O3

    8

    2.580

    0.638

    K11

    O1-O3

    8

    2.753

    0.305

    K12

    O1-O3

    8

    3.154

    0.203

    K13

    O2-O3

    8

    3.031

    0.172

    K14

    O2-O3

    8

    3.358

    0.153

    K15

    O2-O3

    8

    3.585

    0.146

    H1

    O2-Si-O3

    8

    103.03

    0.423

    H2

    O3-Si-O3

    4

    105.53

    0.524

    H3

    O1-Si-O2

    4

    113.11

    0.272

    H4

    O1-Si-O3

    8

    115.32

    0.179

    H5

    O3-Mn2-O3

    8

    87.64

    0.156

    H6

    O3-Mn2-O3

    4

    115.59

    0.182

    H7

    O1-Mn2-O3

    8

    90.70

    0.156

    H8

    O3-Mn2-O3

    4

    68.47

    0.484

    H9

    O2-Mn1-O3

    4

    108.51

    0.212

    H10

    O1-Mn1-O3

    8

    84.71

    0.159

    2

    3N6 3N6

    TABLE I. INTERATOMIC FORCE CONSTANT VALUES (in N cm-1)

    i=1 j=1

    where G-1 stands for the inverse of the G matrix which is describing the kinetic energies in terms of mass-weighted

    cartesian displacements and =

    . The secular equation

    for calculating the frequencies is given by

    FG E 0

    Here G is a matrix connected with the vibrational kinetic energy and F is a matrix of force constants to represent potential energy required for each vibration and thus gives an idea of the bond strength. Molecules are constructed in cartesian coordinates and then transformed to internal coordinates with changes in bond distances and bond angles. Both F and G are symmetrical in nature and E is a unit matrix and is related to the frequency given by = 42c22.

    Fig. 1. Unit cell of Mn2SiO4 in orthorhombic phase

    With the force constants taken as input, the eigen value equation involving 84X84 matrix was solved. It is obvious from Table I that the stretching force constants for Si-O i.e. K1, K2 and K3 show a systematic variation with interatomic distance. The value of K1 is the highest among all corresponding to the smallest interatomic distance Si-O1 in comparison to K2 and K3. For comparison, the results of previous experimental [11] studies are listed in Table II along

    with the present calculated results. There is a good agreement between the theory and experimental results thus establishing the validity of present calculations. The potential energy distribution for each normal mode in Mn2SiO4 is also investigated and the two dominant contributions from force constant are given in the results. The assignment of specific modes have been made observing the atomic displacements in the eigen vectors.

    TABLE II. CALCULATED AND EXPERIMENTAL RAMAN ACTIVE WAVENUMBERS (in cm-1) FOR Mn2SiO4

    frequencies lying between 400 cm-1 to 565 cm-1 i.e. 565cm-1, 511cm-1, 408cm-1 in Ag mode, 560 cm-1, 530cm-1, 403cm-1 in B1g mode, 550cm-1, 427cm-1 in B2g mode and 548cm-1 and 395cm-1 in B3g are mainly contributed by O-Si-O bending force constants given by H1, H2, H3 and H4. Thus we find that all the frequencies > 400 cm-1 are associated with the internal vibrations within the SiO4 tetrahedron. The frequencies < 400 cm-1are low frequency modes which have the contribution of multiple force constants (K4 to K15 and H5 to H10). These frequencies are due to Mn-O stretching force and O-O repulsive force among SiO4 tetrahedra. These

    Mode

    Expt [11]

    Present result

    Two dominant contribution as per PED

    Ag

    935

    944

    K1-40%, K2-29%

    840

    853

    K3-57%, K2-24%

    808

    812

    K1-40%, K2-11%

    575

    565

    H1-33%, K10-13%

    515

    511

    H2-48%, K13-9%

    389

    408

    H3-23%, K13-13%

    291

    318

    H6-19%, K8-12%

    256.

    283

    K13-21%, K9-15%

    244

    247

    K8-30%,K10-15%

    167

    182

    H7-27%, K7-24%

    124

    129

    K7-21%, K8-15%

    B1g

    942

    K1-41%, K2-30%

    858

    K3-52%, K2-27%

    820

    819

    K1-39%, K3-16%

    588

    560

    H1-31%, K10-14%

    546

    530

    H2-50%, K13-8%

    393

    403

    H3-31%, H4-15%

    307

    312

    K7-18%, H6-15%

    288

    273

    K9-18%, H8-10%

    271

    253

    H8-21%, K13-12%

    203

    192

    H7-28%, H6-14%

    155

    168

    K7-31%, H7-12%

    B2g

    882

    K2-82%, K11-3%

    553

    550

    H1-43%, K10-24%

    401

    427

    H4-37%, K12-17%

    319

    338

    H5-29%, K8-19%

    274

    288

    K13-21%, K12-13%

    188

    186

    K8-37%, K9-30%

    119

    123

    H11-20%, K14-12%

    B3g

    892

    866

    K2-84%, K10-4%

    555

    548

    H1-45%, K10-24%

    378

    395

    H4-36%, K11-21%

    304

    318

    H7-26%, K8-28%

    276

    279

    K9- 29%, K13-14%

    223

    226

    K8-20%, K15-13%

    137

    165

    H5-25% , K14-20%

    The inferences drawn from the PED are described below: It is quite evident from Table II that the highest frequencies

    modes are external vibrations which involve the rotation and

    translation of SiO4 tetrahedra and Mn cations. As per our knowledge no other theoretical data is available to compare the calculated infrared Raman and infrared wavenumbers. A precise determination of infrared wavenumbers is required to further establish the present results.

    TABLE III. CALCULATED AND EXPERIMENTAL INFRARED ACTIVE WAVENUMBERS (in cm-1) FOR Mn2SiO4

    Mode

    Expt [11]

    Present result

    Two dominant

    contribution as per PED

    B1u

    875

    883

    K2-81%, K10-4%

    480

    500

    H1-46%, K10-26%

    430

    437

    H4-32%, K11-17%

    350

    365

    H5-22%, K6-20%

    306

    K5-31%, H10-26%

    300

    283

    K5-39%, H10-18%

    240

    228

    H10-34%, K6-17%

    187

    172

    H9-31%, K13-19%

    129

    K6-24%, K5-16%

    B2u

    945

    931

    K1-45%, K2-33%

    860

    884

    K3-51%, K2-20%

    816

    801

    K1-29%, K3-22%

    564

    H1-30%, K10-11%

    512

    514

    H2-40%, H10-13%

    454

    440

    H3-22%, K13-11%

    373

    K12-18%, K6-14%

    340

    322

    H9-31%, H10-19%

    276

    283

    K4-31%, H6-15%

    242

    236

    H8-26%, K7-23%

    198

    K7-23%, H7-29%

    157

    164

    K5-25%, H9-14%

    100

    H8-24%, H5-16%

    B3u

    950

    934

    K1-47%, K2-34%

    912

    889

    K3-53%, K2-20%

    815

    792

    K1-30%, K2-19%

    562

    550

    H1-32%, K10-14%

    490

    502

    H2-42%, K10-11%

    444

    H3-22%, K13-14%

    378

    K5-24%, H10-17%,

    365

    341

    H10-32%, K7-12%

    297

    273

    H7-20%, H8-15%

    204

    K4-33%, H9-24%

    188

    K6-33%, K5-20%

    177

    174

    K12-20%, K5-17%

    129

    K5-22%, K14-15%

    i.e., 944cm-1, 853cm-1, 812cm-1 in A mode, 942cm-1, 858cm-

    1 -1

    g

    -1 -1

    , 819cm

    in B1g mode, 882cm in B2g mode and 866cm in

    B3g mode has the dominant contribution of Si-O stretching interaction i.e K1, K2 and K3. This result is in confirmation with the inferences drawn by Mouri et al. [10] and Stidham et al. [11]. It has been observed that the M-site cations do not participate in the higher frequency modes. A close look at the reveals that identical results are obtained for the highest infrared wavenumbers in each mode and is attributable mainly due to the Si-O stretching. All the middle order

  4. CONCLUSION

Normal coordinate analysis has been performed on Mn2SiO4 olivine to calculate the Raman and the infrared wavenumbers with twenty five short range force constants. It was found that the higher order frequencies are mainly contributed SiO4 tetrahedra while the lower frequencies are dominated by Mn atoms. Eigen vectors associated with Raman and infrared frequencies for tephroite has also been determined. The theoretical results are found to be in good agreement with experimental observed values. The contribution of each force constant has been determined from the potential energy distribution towards the different vibrational modes.

REFERENCES

  1. W. Deer, R. Howie and J. Zussman, 1992. An Introduction to the Rock Forming Minerals. John Wiley, New York.

  2. A.M. Dziewonski, A.L. Hales and E.R. Lapwood, "Parametrically Simple Earth Models Consistent With Geophysical Data", Physics of earth and planetary interiors,vol 10 (1), pp. 1248, 1975.

  3. S. Ni, L. Chou and J. Chang, "Preparation and characterization of Forsterite (Mg2SiO4) bioceramics", Ceram Int., vol 33, pp. 83-88, 2007.

  4. M. Kharaziha and M.H. Fathi, "Improvement of mechanical properties and biocompatibility of forsterite bioceramic addressed to bone tissue engineering materials", J. Mech. Behav. Biomed. Mater., vol 3(7), pp. 530-537, 2010.

  5. R. Pawley, "The reaction talc + forsterite = enstatite +H2O; new experimental results and petrological implications.", Am. Mineralogist, vol 83 (1), pp. 5157,1998.

  6. N. Maliavski, O. Dushkin and J. Markina, "Forsterite powder prepared from water soluble hybrid precursor", AIChE J., vol 43 (11A), pp. 2832 2836, 1997.

  7. Y. Kudoh and H.Takeda, "Single crystal X-ray diffraction study on the bond compressibility of fayalite, Fe2SiO4 and rutile, TiO2 under high pressure", Physica B + C, vol 139, pp. 333-336, 1986.

  8. A. M. Hofmeister and K. M. Pitman, "Evidence for kinks in structural and thermodynamic properties across the forsterite fayalite binary from thin film IR absorption spectra" , Phys Chem Miner, vol 34, pp. 319- 333, 2007.

  9. E. Dachs, C. Geiger, V.von Seckendorff and M. Grodzicki, " A low temperature calorimetric study of synthetic (forsterite-fayalite)

{(Mg2SiO4-Fe2SiO4)} solid solutions: An analysis of vibrational, magnetic and electronic contributions to the molar heat capacity and entropy of mixing", J. Chem Thermodyn, vol 39, pp. 906-933, 2007.

[10] T. Mouri and M. Enami, "Raman spectroscopic study of olivine-group material", Journal of Minerological and Petrological Sciences, vol 103, pp.100104, 2008.

[11] H.D. Stidham, , J.B. Bates and C.B. Finch,"Vibrational spectra of synthetic single crystal tephroite, Mn2SiO4", Journal of Physical Chemistry, vol 80, pp.1226-1234,1976.

[12] T. Shimanouchi, , M. Tsuiboi and T. J. Miyazawa, "Optically active lattice vibrations as treated by the GFmatrix method", Chem. Phys, vol 35, pp.1597-1609, 1961.

[13] K. Fujino, S. Sasaki, Y. Takeuchi and R. Sadanaga, "X-ray determination of electron distributions in forsterite, fayalite, and tephroite", Acta Crystallographica, vol B37, pp. 513-518, 1981.

Leave a Reply