Paper- Numerical Simu- Oh- Amino Salicylic Acid

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Ultra Science, 19(2), 2007, 185-188 NUMERICAL SIMULATION OF THE INTERNAL VIBRATIONS OF OH GROUP IN AMINO-SALICYLIC ACIDS Y.P.SINGH*, RATNESH DASb and R.A.SINGHc *

Department of Physics, Govt. Women’s Polytechnic College, Sagar (MP),470001 E-mail: [email protected] b Department of Chemistry, Dr. H.S.Gour University, Sagar (MP), INDIA, 470001, E-mail: [email protected] c Department of Physics, Dr. H.S. Gour University , Sagar (MP),470003 Abstract Our present work reports the IR spectra of amino substituted salicyclic Acids recorded by FTIR spectrometer and also simulated theoretically. The simulation were performed using GF matrix and AM1, PM3, DFT method. In this work following steps were taken: optimizing the geometry, computing the IR spectra and comparing it with experimental spectra. Assuming Cs point symmetry, vibrational assignments for the observed frequencies have been proposed. The spectra exhibit distinct features originating from low frequency vibrational modes caused by intra-molecular motion. Keywords 3-amino salicylic acid, 4-amino salicylic acid, 5-amino salicylic acid, OH group, FTIR spectra, vibrational spectra, AM1, PM3, DFT,G-F Matrix Introduction Salicylic

acid contains both a hydroxyl and a carboxyl group, which react with either an acid

or an alcohol. The presence of the carboxyl group appears to enhance the antiseptic property. Many hair tonics and remedies for athlete’s foot, corns and warts employ the keratolytic action of salicylic acid 1. Volvo, Colombo and Furic

2

calculated normal coordinates for salicylic acid molecule and

proposed the assignment of the observed Raman and IR spectra. Boczar Marck et al 3 studied theoretical simulation of the ν s stretching band for salicylic acid takes into account adiabatic couplings between the high-frequency O-H stretching and the lowfrequency intermolecular O.......O stretching modes. Jadrijevic et al 4 analyzed the structures and the specral properties of salicylic acid and benzoic acids by means of FT-IR and NMR spectroscopies. With the availability of powerful computers and the advent of efficient density functional theory (DFT) methods implemented in standard codes, structure and dynamics of systems containing a few tens of atoms (or even more) are now within reach. Vibrational spectra of small molecules of

biological or pharmaceutical relevance are routinely treated combing DFT electronic structure calculations with a harmonic analysis 5. We compared experimental results with calculated frequencies of OH group of aminosalicylic acids using force matrix method and AM1, PM3 and DFT method. These methods were able to account breadth of spectrum as well as description of vibrational modes to encourage the application

of

a

similar

procedure

to

a

larger

and

more

complex

group.

COMPUTATIONAL AND THEORETICAL DETAILS In noncomplex molecules, the G F Matrix 13 is given by:G tt’= Σ3Ni=1 (B ti B t’i’) 1/ mi

where t, t’ = 1,2,3,……, 3N-6

In which m i is the mass of the atom to which the subscript I refers and B ti , Bt’i’ are constants determined by geometry of molecule. Internal coordinate St are related with Cartesian displacement coordinate ξi as : St = Σ 3Ni=1 Bti ξi

where t = 1,2,3….., 3N-6

On solving, G.F. matrix for any atom α is obtained as: G tt’= Σ3N α =1 μ α St α . St’ α Where dot represents the scalar product of two vectors and μ α = 1/m α , the reciprocal of the mass of atom α The AM1 and PM3 semi empirical approaches were performed as implemented in MOPAC program 6 and the PRECISE keywords were used. DFT calculations were performed using HYPER CHEM program 7 at the B3LYP 8 levels of theory with 6-31G* basis set 9 . The vibrational IR spectra were calculated at the B3LYP/ 6-31G* levels of theory. We have transformed the harmonic force fields, determined initially in the Cartesian coordinates, were transformed to the force fields in the internal local coordinates. The force fields obtained were used to calculate the potential energy distribution (PED)10. Contributions greater than 10% are given. RESULTS and DISCUSSIONS We can get information from computational vibrational spectra only when we compare calculated frequencies with experimental spectrum. Our results are given in table 1. Due to anharmonicity, the harmonic vibrational frequencies were found to be lowered by1 to 3% in almost all cases except AM1 method. The number of internal vibrations for a group is given by 3m-3, where m is the number of atoms in the group. Thus OH has 3 modes of vibrations. Out of these, 2 modes belong to a’ and one

mode to a”. The a’ modes are O-H stretching & in-plane-bending COH and mode for a” is out-ofplane wagging mode. Volovsek et al2 studied salicylic acid and they got OH stretching at 2928 cm −1 , in-plane-bending at 1448 cm −1 and wagging at 573 cm −1 . Zerbi and Sandroni result. A.K.Tiwari

14

13

also got similar

observed OH stretching at 3610 cm −1 , in-plane bending OH at 1195 cm −1

and wagging at 650 cm −1 . Chad C. Trout et al15 observed OH stretching at 3419 cm −1 , OH inplane bending at 1207 cm −1 , but he didn’t study low frequency spectra, similarly M. Jadrijevic et al4 observed OH stretching at 3374 cm −1 and OH Bending at 1461 cm −1 .Humbert et al

16

attributed the 1301cm-1 peak to a benzene ring stretch coupled to OH in-plane bending In present work we get frequencies for them as :Table 1 Internal vibrations of OH group Mode of Vibration O-H Stretching a’ Bending C-OH

a”

Wagging

3-AminoSalicyclic Acid (cm-1) 3396 (E) 3369.1(AM1) 3373.1(PM3) 3379.1(GF) 3381.3(DFT) 1475(E) 1512.6(AM1) 1519.4(PM3) 1493.8(GF) 1481.5(DFT)

4-AminoSalicyclic Acid (cm-1) 3389(E) 3341.2(AM1) 3338.7(PM3) 3371.5(GF) 3394.6(DFT) 1489(E) 1515.7(AM1) 1523.1(PM3) 1501.3(GF) 1499.4(DFT)

5-AminoSalicyclic Acid (cm-1) 3394(E) 3358.2(AM1) 3338.9(PM3) 3380.4(GF) 3384.7(DFT) 1498(E) 1532.7(AM1) 1525.9(PM3) 1515.8(GF) 1505.6(DFT)

310(E) 327.1(AM1) 328.3(PM3) 318.3(GF) 317.5(DFT)

305(E) 321.6(AM1) 328.79PM3) 317.4(GF) 311.4(DFT)

315(E) 329.1(AM1) 331.6(PM3) 322(GF) 320.6(DFT)

E :- Experimental frequencies GF:- Theoretical frequencies calculated by GF Matrix method AM1:- Theoretical frequencies calculated by quantum mechanical AM1 MOPAC method PM3:- Theoretical frequencies calculated by quantum mechanical PM3 MOPAC method DFT:- Theoretical calculations were performed using HYPER CHEM program at the B3LYP levels of theory with 6-31G* basis set

CONCLUSIONS Theoretical semi-empirical quantum mechanical AM1, PM3, DFT and GF matrix calculations of the geometry and vibrational frequencies of the –OH group of o-,m-,p- amino salicylic acids are

presented in this paper and compared with infrared spectra. The calculated geometries and frequencies agree well ( for DFT and G.F. Matrix) with the experimental ones, but there are some differences between frequencies mainly due to intermolecular interactions, anharmonicity and computational basis set. The results indicate that, the exchange functional proposed by Becke and the correlation functional of Lee, Yang and Parr with 6-31G* basis set is the optimal model for studying o-,m-,p- salicylic acids. ACKNOWLEDGEMENTS The authors are grateful to Director, Directorate of Technical Education-Madhya Pradesh, Bhopal and Head, Department of Physics, Dr. H.S.Gour University, Sagar (MP), India, National Institute of Advanced Industrial Science and Technology, Japan for IR spectra and Hypercube Inc for providing Hyperchem Package 7 for molecular modeling.

Figure 1: FT-IR Spectra of 3-amino salicylic acid

Figure 2: FT-IR Spectra of 4-amino salicylic acid

Figure 3: FT-IR Spectra of 5-amino salicylic acid

Refrences 1.

Foye’s Principle of Medicinal Chemistry, 5th, Edition, Lippincott Williams and Wilkins, New York, (2002)

2.

V.Volvo ek, L.Colombo, K.Furic; J. Raman Spect; 14, 5, 347-352, (1983) 3.

Boczar Marek, M.J.Wojcik and A.Zieba, Chemical Physics, 50, 4, (2002)

4.

M.Jadrijevic,M.Takac and D.Topic, Acta Pharm, 54, 177-197, (2004)

5.

J.M. Bakker, G. Meyer, M. Kabelac and M.S. de Vries, Phy Chem Chem Phys, 6, 2810, (2004).

6.

Win MOPAC- Molecular Orbital Program, Fujitsu Limited, (1997)

7.

Hyperchem Package 7 for molecular modeling, Hypercube Inc, (2002)

8.

A.D.Becke, J. Chem Phys. 98,5648, (1993)

9.

W.J.Here, L. Random, P.V.R. Schlyer and J.A.Pople, Ab initio Molecular- Orbital Theory, Wiley, New York (1989)

10

Florio, E.L. Sibert and T.S. Zwier; Faraday Discuss, 118, 315, (2001).

11

Antony, G.V.Helden, G. Meijer and B. Achmidt, J. of Chemical Physics,122, (2005).

12

M.Florio, T.S.Zwier and E.L.Sibert , J. Chem. Phy; 118, 4, (2003).

13

Zerbi and Sandroni, Spectrochim Acta, 24A, 511, (1968)

14

A.K.Tiwari, Ph.D. Thesis, Dr. H.S.Gaur University, Sagar, (2004)

15

Chad C. Trout, T.J.Tambach and J. D. Kubicki, www.engr.psu.edu, (2005)

16

B.Humbert, M. Alnot and F. Quiles, Spectrochim Acta, 54A, 365, (1998).

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