Spectroscopic Characterization, NLO Properties and DFT Study of Amino Acid Single Crystals of Glycine Nickel Chloride

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Spectroscopic Characterization, NLO Properties and

DFT Study of Amino Acid Single Crystals of Glycine

Nickel Chloride

A Shiny Febena, M Victor Antony Raj, J Madhavan

To cite this version:

Spectroscopic Characterization, NLO Properties and DFT Study of Amino Acid

Single Crystals of Glycine Nickel Chloride

A. Shiny Febena1, a, M. Victor Antony Raj1, J. Madhavan1

1 – Department of Physics, Loyola College, Chennai, India a – shinyfebena@gmail.com

DOI 10.2412/mmse.48.92.693 provided by Seo4U.link

Keywords. DFT, HOMO-LUMO, TG-DTA, SHG, Kurtz and Perry powder.

ABSTRACT. Semi Organic nonlinear optical single crystal of Glycine Nickel Chloride was successfully grown by the

Slow Evaporation Solution Growth Technique (SEST). Formation of the crystalline compound, the cell parameters and the non-centrosymmetric nature was confirmed by single crystal X-ray diffraction studies.Structural confirmation was done by identifying the vibrational modes using FT- IR spectroscopic studies. The quantum chemical analyses were performed by density functional theory (DFT) using B3LYP/6-31G (d, p) basis set. The calculated first order hyperpolarizability of GNC is 0.233 x 10-30 _{e.s.u. The HOMO and LUMO energies show that charge transfer occurs} within molecule. The thermal behavior was analyzed by simultaneous TG-DTA studies. The UV–visible studies were employed to examine the high optical transparency and influential optical constants for tailoring materials suitability for optoelectronics applications. The second harmonic generation (SHG) measured by the Kurtz and Perry powder technique was found to be 3.2 times that of KDP. The result suggests Glycine Nickel Chloride as a promising candidate for optical devices applications.

Introduction. Advanced optoelectronic technology requires nonlinear optical (NLO) materials for

frequency conversion, optical modulation and optical switching [1, 2]. Efforts have been made on the amino acid mixed organic and inorganic complexes for suitable device applications. The intense charge transfer between metal and ligands causes NLO nature and good transparency in visible region and high resistance to optical damage [3, 4].In the present work, glycine with nickel chloride formed a non-centro symmetric glycine nickel dichloride dihydrate crystals.

Experimental Details

Synthesis and Solubility of GNC. High purity Glycine and Nickel (II) chloride were used for

growing single crystals of GNC. The synthesized salt was purified by repeated crystallization process. Fig. 1 shows the solubility curve of GNC. Supersaturated solution of GNC was prepared in accordance with the solubility data. A few drops of H2O2 were added to the mother solution as

antimicrobial substance.Good optical grade crystals of dimension up to 9 x 2 x 4 mm3were harvested. Fig. 2 shows the photograph of as grown GNC single crystal.

Fig. 1. The solubility curve. Fig. 2. Photograph of as grown crystal.

Results and Discussion.

X-ray diffraction analysis. Among the grown crystals of GNCwell-shaped, transparent, single

crystal was selected and it was subjected to single crystal XRD analysis usingENRAF NONIUS CAD4 X-ray diffractometer with MoK radiation at room temperature. From the analysis data it was

observed that the crystal belongs to monoclinic crystal system having non-centrosymmetry with P21

space group. The details of crystal parameters are summarized in Table 1. XRD pattern of GNC is shown in Fig. 3. Theoretically Simulated XRD pattern of GNC single crystal with indexed peak is given in Fig. 4. Both the patterns coincide well.

Computational Details and Molecular Geometry. The optimized molecular structure of GNC and

corresponding vibrational harmonic frequencies were calculated using Beckee-3-Lee-Yag-Parr (B3LYP) combined with 6-31 G(d, p) basis set [5].The optimized molecular structure of the isolated GNC molecule is calculated using Density Functional Theory at B3LYP/6-31 level is shown in Fig. 5.

Vibrational assignments. It is found that GNC molecule has 19 moieties and is in stable

conformation with C1 symmetry then exhibits 51 normal modes of vibrations. The normal modes of

GNC is distributed amongst the symmetry species as

Γ3N-6 = 35A′ (in-plane) +16A″ (out-of-plane) respectively.

Fig. 4. Theoretically simulated XRD pattern.

Table 1. Crystal parameters of GNC.

Empirical Formula C2H9Cl2NNiO4 Unit cell dimensions

Formula weight 240.71 a = 8.183 Ǻ b = 5.480 Ǻ c = 8.315 Ǻ α =γ=90° β=90.97° Wave length 0.71073 nm

Crystal system, Space group Monoclinic P21

Fig. 5. Atomic numbering system. Fig. 6. Experimental FT-IR.

FT-IR Analysis. The FT-IR spectrum was recorded in the range 500 cm-1 to 4000 cm-1, using KBr pellet technique on IFS 66V FT-IR Spectrometer. Recorded FT-IR spectrum is shown in Fig. 6.

C-N vibrations. The stretching vibration bands of C-N ring occur in the region 1600 cm-1-1500 cm- 1[6]. The theoretical and experimental peaks appear at 1500 cm-1 and 1496 cm-1 respectively.

NH2 vibrations. The NH2 asymmetric stretching vibrations [7] give rise to a strong band in the region

3390±60 cm-1 _{and the symmetric NH}

2 stretching is observed as weak band in the region 3210±60

cm- 1. The theoretical asymmetric stretching appears at 3359 cm-1 and 3422 cm-1 and the experimental value coincides well at 3378 cm-1.

C-Cl vibrations. The band at 366 and 367cm-1 is assigned for C-Cl in-plane bending for FT-IR 144 cm-1 _{and 142 cm}-1 _{is for out-of-plane bending vibrations for FT-IR [8]. The vibrational assignments}

of fundamental modes of GNC by DFT methods are reported in Table 2.

Hyperpolarizability. In the second-order NLO materials designMolecular hyperpolarizability β is

HOMO and LUMO analysis. The HOMO–LUMO energy gap of GNC is calculated at

B3LYP/6-31G (d, p) levels are shown in Fig. 7.

HOMO energy (B3LYP) = -0.272a.u. LUMO energy (B3LYP) = -0.046 a.u. HOMO–LUMO energy gap (B3LYP) = 0.226 a.u.

Table 2. Selected Experimental and Calculated B3LYP/6-31 G (d, p) level of vibrational frequencies of GNC. No. Frequency cm -1 _{Spectroscopic} assignment B3LYP Expt. 1. 515.9829 516 COO- d+ CCl st 2. 655.1160 661 COO- _{d +NH opd} 3. 691.5787 674 NH opd+NH2 wag 4. 875.2665 887 CH3 opb 5. 953.3112 913 C=O opd 6. 1099.547 1029 OH ipb 7. 1165.119 1113 II CH ipd 8. 1265.0148 1254 COO- st&b 9. 1456.8423 1447 COO- sym st 10. 1500.4299 1496 NH3+ sym d+CN st 11. 1633.7591 1622 NH3+ asy d 12. 2314.5824 2029 CH vib(IR) 13. 3359.1695 3373 NH3+ asy st

SHG efficiency studies.A Q-switched Nd: YAG laser beam of 1064nm wavelength with 6.5mJ input

power, 8ns pulse width was used. SHG was confirmed by the emission of green light. Using reference material as potassium dihydrogen phosphate (KDP), the output of SHG signal was compared and found that the SHG conversion efficiency of GNC is 3.2 times that of KDP.

Optical absorption spectrum. The optical absorption spectral analysis of GNC was recorded

between 190nm and 1100nm. It is evident that GNC crystal has UV cut off at 236 nm. The recorded absorption spectrum is shown in Fig. 8.A graph to estimate the direct band gap valuehas been plotted between photon energy and (αhν)2 where α is the absorption coefficient and hν is the energy of the incident photon. From the Fig. 9, the band gap energy is found to be 3.27 eV.

Thermo gravimetric analysis. The weight loss was observed in four steps. In the first stage the

weight loss starts at 44.4°C and completes at 175°C this may be due to adsorption of water molecules as the loss is recorded as 8.47%. On further heating, the second mass loss starts at 175°C and ends at 375°C. The maximum weight loss of 48.89% is observed in this stage. The third and fourth stage extends from 375°C to 910 °C with a total weight loss of 25.86%. The DTA curve shows sharp endothermic peaks which are in good agreement with TGA trace. TGA and DTA graphs are shown in Fig. 10.

Fig. 10. TGA and DTA curve of GNC crystal.

Summary. In this work, report on the preparation, growth, and the characterization of Single crystal

of an aminoacid based nonlinear optical material GNC have been reported. XRD data indicates the monoclinic structure of GNC.FT-IR analysis confirmed the functional groups. The UV-Vis spectrum reveals minimum absorption in the entire visible region. Thermal stability with high power efficiency exhibits the potential of GNC in the field of laser and opto-electronic device fabrications.

References

[2] Madhavan J , Aruna S , Anuradha A , Premanand D, Vetha Potheher I , Thamizharasan K, Sagayaraj P, J Optical Materials 29 (2007) 1211–1216.DOI.org/10.1016/j.optmat.2006.04.013. [3] Arularasan P, Thayanithi V, Mohan R, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy 144 (2015) 8–16.DOI: 10.1016/j.saa.2015.01.078.

[4] Joseph G P, Korah I, Rajarajan K, Thomas P C, Vimalan M, Madhavan J and Sagayaraj P (2007), Cryst. Res. Technology, Vol. 42, pp. 295-299. DOI: 10.1002/crat.200610816.

[5] Frisch M.J, et al, Gaussian 03, Revision C.02, Gaussian Inc.,Wallingford, CT, 2004.

[6] Socrates G, Infrared and Raman Characteristic Group Frequency, third ed., Wiley, New York, 2001.

[7] Roeges N G P, A Guide to the Complete Interpretation of the Infrared Spectra of Organic Structures, Wiley, NY, (1994).

[8] Krishnan A R, Saleem H, Subash Chandara Bose S, Sundaraganesan N, Sebatain S, Spectrochim. Acta A 78 (2011) 582. DOI.org/10.1016/j.saa.2010.11.027.

[9] Rice J E, Handy N C., J Chem Phys., 94 (1991)4959. DOI.org/10.1063/1.460558.

[10] Li H, Han K, Shen X, Lu Z, Huang Z, Zhang W, Zhang Z, Bai L, J Mol Strut (Theochem), 767(2006)113. DOI.org/10.1016/j.theochem.2006.05.008.

Cite the paper A. Shiny Febena, M. Victor Antony Raj, J. Madhavan, (2017). Spectroscopic Characterization, NLO Properties and DFT Study of Amino Acid Single Crystals of Glycine Nickel Chloride. Mechanics, Materials