A combined experimental (IR, Raman and UV–Vis) and quantum chemical study of canadine

Accepted Manuscript A combined experimental (IR, Raman and UV–Vis) and quantum chemical study of canadine

Bhawani Datt Joshi, Anubha Srivastava, Poonam Tandon, Sudha Jain, A.P. Ayala PII: DOI: Reference:

S1386-1425(17)30807-7 doi:10.1016/j.saa.2017.10.008 SAA 15514

To appear in:

Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy

Received date: Revised date: Accepted date:

9 February 2017 3 September 2017 3 October 2017

Please cite this article as: Bhawani Datt Joshi, Anubha Srivastava, Poonam Tandon, Sudha Jain, A.P. Ayala , A combined experimental (IR, Raman and UV–Vis) and quantum chemical study of canadine. The address for the corresponding author was captured as affiliation for all authors. Please check if appropriate. Saa(2017), doi:10.1016/ j.saa.2017.10.008

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ACCEPTED MANUSCRIPT A combined experimental (IR, Raman and UV-Vis) and quantum chemical study of canadine Bhawani Datt Joshia,b*, Anubha Srivastavac, Poonam Tandonc*, Sudha Jaind, A. P. Ayalab a

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Department of Physics, Siddhanath Sc. Campus, Tribhuvan University, 10406, Nepal. b Departamento de Fisica, Universidate Federal do Ceará, C. P. 6030, 60.455-900, Fortaleza, CE, Brasil. c Department of Physics, University of Lucknow, University Road, Lucknow 226 007, Uttar Pradesh, India. d Department of Chemistry, University of Lucknow, University Road, Lucknow 226007, Uttar Pradesh, India

________________________ *Corresponding author. Tel.: +977-9841580777; +91 522 2782653; fax: +91 522 2740840. E-mail address: [email protected], [email protected] (B. D. Joshi), [email protected] (P. Tandon)

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ACCEPTED MANUSCRIPT Abstract Plant based natural products cover a major sector of the medicinal field, as such focus on plant research has been increased all over the world. As an attempt to aid that research, we have performed structural and spectroscopic analysis of a natural product, an alkaloid: canadine. Both ab initio Hartree-Fock (HF) and density functional theory (DFT) employing

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B3LYP using 6-311++G(d,p) basis set were used for the calculations. The calculated

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vibrational frequencies were scaled and compared with the experimental infrared and Raman

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spectra. The complete vibrational assignments were made using potential energy distribution. The structure-activity relation has also been interpreted by mapping electrostatic potential

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surface and evaluating the reactivity descriptors, which are valuable information for quality control of medicines and drug-receptor interactions. Natural bond orbital analysis has also

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been performed to understand the stabilty and hyperconjogative interactions of the molecule. Furthermore, UV-Vis spectra have been recorded in an ethanol solvent (EtOH) and the

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electronic property has been analyzed employing TD-DFT for both gaseous and solvent

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phase. The HOMO and LUMO calculation with their energy gap show that charge transfer occurs within the molecule. Additionally, the nonlinear optical properties of the title

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compound have been interpreted that predicts it’s the best candidate for the NLO materials.

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Keywords: CAD, ab initio, DFT, vibrational spectroscopy, NBO, NLO properties

1. Introduction Literature reveals the traditional use of medicinal herb Goldenseal (Hydrastis canadensis L., belonging to the genus, Menispermaceae) for mild pathological conditions such as gastritis, colitis, duodenal ulcers, loss of appetite, and liver disease [1-3]. Benzylisoquinoline alkaloids viz; berberine, β-hydrastine, canadine, and canadaline have

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ACCEPTED MANUSCRIPT active components of Goldenseal. Canadine (CAD) possesses ventricular anti-fibrillatory effects (that may be attributed to its blockade of Na+, K+, and Ca2+ currents) [4], a potent inhibitor of platelet aggregation (in vitro and in vivo triggered by ADP, collagen, and arachidonic acid), and promising antithrombotic drug [5]. Having non-quaternary nitrogen and two non-aromatic rings, it has an antioxidant activity [6], and display very low

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cytotoxicity [7]. Algarra et al. [8] analyzed different separation techniques for CAD alkaloid

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in goldenseal extracts. Also, Pingali et al. [3] determined the crystalline structure of canadine

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molecule by single crystal diffraction technique. Its chemical structure is shown in the Fig. 1(a).

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Spectroscopic techniques, when combined with the quantum chemical calculations, are emerging as one of the most valuable methods for studying the structural behavior and to

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gain insight into the electronic structures of alkaloids at microscopic level [9, 10]. As the natural products show a diversity of chemical structures, in the recent years there has been

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increasing interest in the application of ab initio calculations to alkaloids as demonstrated in

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our earlier studies [9, 11, 12] as well as in others [13-16]. The theoretical investigations on the molecular properties can facilitate the solutions confronted in the experimental

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techniques.

A literature search reveals that neither the experimental infrared, Raman, and UV-Vis

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spectral analyses nor the theoretical calculations on molecular geometry, vibrational modes, natural bond orbital (NBO) and nonlinear optical (NLO) properties of the title molecule has been investigated so far. We would like to eliminate this deficiency observed in the literature. The main objective of this study is to investigate the structural and electronic properties of the title compound with the help of vibrational spectroscopic techniques and quantum mechanical calculations using both ab initio Hartree-Fock (HF) and the density functional theory (DFT) [17]. To understand the various conjugative and hyperconjugative interactions

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ACCEPTED MANUSCRIPT as well intermolecular interactions that would form the H-bonded network within the molecule, natural bond orbital (NBO) analysis has been performed. Also, to interpret the structural-activity relationship and reactive sites of the molecule, molecular electrostatic potential (MEP) and reactivity descriptors have been calculated. Further, the nonlinear (NLO)

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property reveals that the title compound can be used as a good NLO material.

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2. Experimental details

Infrared spectra of CAD were recorded on a Bruker TENSOR 27 FT-IR spectrometer

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with a spectral resolution of 4 cm-1 in the region 300-4000 cm-1. Pellets of solid samples were

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prepared from mixtures of KBr and the sample in 200:1 ratio using a hydraulic press. The Raman spectra were recorded using an efficient visible Raman setup, Ar-514 nm,

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and 12 mW, at room temperature. An excitation laser of wavelength 514 nm was emitted from an Argon ion laser source with a power of 12 mW was used to record the vibrational

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spectra. The scattered Raman light was collected in a back scattering geometry using a

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microscope objective (ULW x50). The scattered light was dispersed using a monochromator with 1200 grooves/mm diffraction grating, and an entrance slit width of 200 micrometers.

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The Raman signals were detected using liquid nitrogen cooled charged coupled device (CCD) with an optimal sensitivity in the visible range. The total exposure time for each sample was

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5 sec and averaged over five accumulations. The ultraviolet absorption spectra of the molecule were examined in the range 200800 nm using a Varian - Cary 50 Bio, UV-Vis Spectrophotometer equipped with a 10 mm quartz cell. The UV pattern is taken from a 1x10-5 M solution of CAD, dissolved in ethanol at 20 ˚C.

3. Computational details

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ACCEPTED MANUSCRIPT The molecular structure, vibrational frequencies, and energies of the CAD were computed employing the DFT [17] method using Gaussian 09 program [18] package and Becke’s three parameters (local, non-local, Hartree-Fock) hybrid exchange functional with Lee-Yang-Parr correlation functional (B3LYP) [19-21]. First, the B3LYP/6-311++G(d,p) level of theory has been used for optimization protocol. Using these optimized parameters,

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the vibrational frequencies have been calculated at same level theory, which were used

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further for the spectra simulation. The split valence basis set 6-311++G(d,p) augmented by

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‘d’ polarization functions on heavy atoms and ‘p’ polarization functions on hydrogen atoms as well as diffuse functions for both hydrogen and heavy atoms [23, 24] have been used. The

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absolute Raman intensities and infrared absorption intensities were calculated in the harmonic approximation at the same level of theory as used for the optimized geometries.

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The vibrational assignments of normal modes were performed and the PED was calculated employing Gar2ped program [25] along with the internal coordinates using localized

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symmetry. For this purpose, a complete set of 132 internal coordinates were defined using

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Pulay’s recommendations [26, 27].

The graphical representation of the calculated Raman and IR spectra were made using

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GaussView program [28]. Visualization and confirmation of calculated data were done by using the Chemcraft program [29]. Isoelectronic molecular electrostatic potential surface

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(MEP) was mapped with GaussView program [28] using B3LYP/6-311++G(d,p) basis. Mulliken atomic charges, HOMO–LUMO gap (∆E), ionization potential, dipole moments and total energy have also been obtained for the optimized geometry. A theoretical time dependent density functional theory (TD-DFT) [23, 24] method was used to calculate the electronic absorption parameters in the gas phase, employing 6-31G basis set and the solvent effects (in EtOH solvent) were taken into account by means of integral equation formalism polarizable continuum model (IEF-PCM) [30-32]. NBO [17] analysis, which deals about the

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ACCEPTED MANUSCRIPT intra- and intermolecular charge delocalization between the bonds of a molecular system, has been performed at the DFT/B3LYP level of theory. Further, the reactivity descriptors have been calculated using B3LYP/6-31G(d,p) basis.

Geometry optimization and energies

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4.1.

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4. Results and discussions

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Starting from the molecular conformation of CAD in the asymmetric unit of the crystalline structure [3], the geometry optimization was performed as the first task without

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any constraints to the potential energy surface. The optimized structural parameters, using energy minimization, were used in vibrational frequency calculation to characterize all

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stationary points as minima. The ground state optimized structure of the molecule is presented in Fig. 1(b). The optimized structure is remarkably similar to the experimental one

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[3]. Both the optimized and experimental molecular conformations were compared by

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superimposing them using a least-square algorithm that minimizes the distance between the corresponding non-hydrogen atoms, as shown in Fig. S1 (Supplementary material). For

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clarity, all the hydrogen atoms are removed. The good agreement between the optimized and the experimental structure show that the optimized structure makes a replica of the

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experimentally observed conformation. The relative energies of the molecule are calculated employing ab initio HF and DFT functional. The energy calculated by DFT (-709572.532 kcal/mol) is lower, showing more stability, than the one calculated by HF (-705094.857 kcal/mol). The enthalpy difference between these two theories is 17.586 kcal/mol. A comparison of the optimized values of structural parameters (bond length, bond angle and torsion angle) with the observed values is given in Table S1 (Supplementary material). In general, the bond lengths do not differ by

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ACCEPTED MANUSCRIPT more than 0.02 Å, except the bonds O1-C18 and O3-C9, which differ by 0.06/0.07 and 0.015/0.03 Å in the DFT/HF, respectively. The bond angles do not differ by more than 3o, except the angles C9-O3-C19 and C6-N1-C15, which differ by 4.4/4.6o and 2.9/3.3o in the DFT/HF. Similarly, the dihedral angles do not differ by more than 10o, except the angles C20-O4-C10-C9, C20-O4-C10-C11, and C7-N1-C15-C14, which differ by 13.8/12.2o,

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4.2. Molecular Electrostatic Potential (MEP) Surface

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14.7/12.4o and 9.8/10.4o in the DFT/HF, respectively.

The MEP provides a visual method to understand the sites of the relative charge

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distribution in a molecule [12, 24]. In the generated surface, negative electrostatic potential colored in shades red, whereas, positive one colored in the shades of blue. A molecule shows

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its non-polar behavior if the surface is largely white or lighter color shades. Potential increases in the order red < orange < yellow < green < blue. The MEP of CAD mapped using

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the DFT/6-311++G (d,p) output is shown in the Fig. 2. The highest negative potential with

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red blobs is visible over the regions near nitrogen in ring and oxygen atoms of methoxy groups. The yellowish blob reflects less negative potential, is visible over the oxygen atoms

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of ring R1. A positive charge is localized near the hydrogen atoms of the methyl group. The

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value of Mulliken charges is presented in the Table S2 (Supplementary material).

4.3. Natural bond orbital (NBO) analysis NBO analysis is one of the efficient method for studying hybridization, conjugative interactions, covalence effects and charge transfer in polyatomic wave functions [11, 12]. The information from the first-order density matrix of the ab initio calculations develops a unique set of atomic hybrids and bond orbitals, which leads to “Lewis structure”. It helps in the investigation of intra- and intermolecular interactions among bonds. In the present work,

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ACCEPTED MANUSCRIPT utilizing the second-order micro-disturbance theory analysis, we have accounted some of the electron acceptors, donor orbitals and the interacting stabilization energy, E(2). The hyperconjugative interaction energy was deduced from the second-order perturbation approach [33-35]. The most important interaction between ‘‘filled’’ (donor) Lewis type NBOs and ‘‘empty’’ (acceptor) non-Lewis NBOs are reported in Table 1.

*C10-C11 bond of ring R5 which increase the ED (0.409e) leading to the

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C8-C9 to

electrons from C12-C13 and

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There occurs a strong hyperconjugative interaction of

NBO further conjugates with

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stabilization energy of 19.44 and 21.31 kcal/mol, respectively. This enhanced

*C10-C11

*C8-C9 resulting to high stabilization of 228.59 kcal/mol.

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Another hyperconjugative interactions were observed from

C4-C16 and

C17-C18 to

*C2-C3 bond of ring R2, and from C8-C9 and C10-C11 to *C12-C13 of ring R5 which

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increase the EDs of 0.366e and 0.363e, respectively. Similarly, the enhanced / *C2-C3 NBOs further conjugate to

*C17-C18

*C4-C16 leading to stabilization of 137.61/141.91

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kcal/mol, respectively. The interactions related to the resonance in the molecule, are electron

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donation from LP(2)O1/LP(2)O2 to antibond acceptors

*C17-C18 / *C2-C3 of ring R2

(24.98 /25.28 kcal/mol), and from LP(2)O4 to the antibond acceptor *C10-C11 of ring R5

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(27.78 kcal/mol). The interactions are confined between those atoms which are attached with the rings. A comparison of Mulliken and NBO charges is presented in the Table S2

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(Supplementary material).

Selected Lewis (bond or lone pair) NBO orbitals of investigated molecule with their valence hybrids corresponding to the various interactions are listed in Table S3 (Supplementary material). The valence hybrids analyses of NBO orbitals show that all the C– N bond orbitals are polarized towards the nitrogen atom (60.95 - 61.60% at N), whereas the C–O bond orbitals are polarized towards the oxygen atom (67.04 - 68.48% at O). Therefore, they consist with the maximum electron density on the nitrogen and oxygen atoms. The 8

ACCEPTED MANUSCRIPT electron density distribution around the imino group also influences the polarity of the compound.

4.4. Chemical reactivity

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4.41. Global reactivity descriptor

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Electrophilicity and hardness are two important molecular properties, which are

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useful for interpreting and understanding the stability and reactivity of molecular system [21]. According to the Hohenberg and Kohn (HK) theorems [17], the energy of the basic state of

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an electronic system is a functional of electron density. On the basis of Koopman’s theorem [21], global reactivity descriptors; electronegativity (χ), chemical potential (σ), global

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hardness (η), global softness (S) and global electrophilicity index (ω) were calculated using the energies of frontier molecular orbitals EHOMO, ELUMO and given by relations:

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χ = - ½[EHOMO + ELUMO]

η = ½[EHOMO + ELUMO]

ω = σ2/2η

………….. (4) …………… (5) ……………… (6)

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∆Nmax = - σ/η

………….. (3)

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S = ½(η)

……….. (2)

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σ = - χ = ½[EHOMO + ELUMO]

…….…….. (1)

According to Parr et al. 1999 [36] ω, a positive and finite quantity is a global reactivity index similar to

(a measure of the resistance of a system to transfer charge), and

σ. The direction of the charge transfer is completely determined by the electronic chemical

potential of the molecule because an electrophile is a chemical species capable of accepting electrons from the environments. Therefore, its energy must decrease upon accepting the electronic charge and electronic chemical potential must be negative. The values of frontier

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ACCEPTED MANUSCRIPT energy levels (EHOMO, ELUMO), energy band gap (ΔE), χ, σ, η, S, ω, and additional ΔN for CAD are listed in the Table S4 (Supplementary material). The calculated high value of the electrofilicity index (ω) shows that the molecule behaves as a strong electrophile.

4.42. Local Reactivity Descriptors

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Using Hirschfield population analysis of neutral, cation and anion state of molecule,

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Fukui functions (fk+, fk-, fk0) [36-39], are calculated at same calculation method B3LYP/6-21 G(d,p) using following relations: fk+ = [q(N+1) - q(N)] for nucleophilic attack

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……………….. (7)

fk- = [q(N) - q(N-1)] for electrophilic attack

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fk0 = ½[q(N+1) - q(N-1)] for radical attack

………………… (8) ………………. (9)

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where N, N-1 and N+1 are total electrons present in neutral, cation and anion state of molecule, respectively.

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Local softness (sk+, sk-, sk0) and local electrophilicity indices (ωk+, ωk-, ωk0), also used

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to describe the reactivity of atoms in the molecule, are calculated using the following equations:

sk+ = S fk+, sk- = S fk-, sk0 = S fk0

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………………… (10)

ωk+ = ω fk+, ωk- = ω fk-, ωk0= ω fk0

……………….. (11)

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where +, −, 0 signs show nucleophilic, electrophilic and radical attack, respectively. The calculated values of Fukui functions, electrophilicity descriptors, and the nucleophilicity descriptors are listed in the Table 2. The high value of fk- at O2 and O1 atoms indicate that these sites are more prone to nucleophilic attack. Similarly, the sites at C1, C12, and C20 are more prone to electrophilic attack due to having maximum value of fk+.

4.5. UV spectroscopy and HOMO-LUMO analysis

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ACCEPTED MANUSCRIPT The UV-Vis absorption spectrum of CAD is shown in the Fig. 3 with the absorption bands at 294 and 286 nm in EtOH solvent. Both the frontier molecular orbitals (FMOs), highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) are the most important orbitals participated in a chemical reaction. The transition of an electron between HOMO and LUMO is a principal factor that determines the easiness of

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chemical reaction and its path, irrespective to the intra- and intermolecular processes. Higher

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the gap between these two bands ( E) more is the stability of the system and vice versa.

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Here, we have demonstrated the molecular orbital both in the gas and solvent phases as an example to compare the effect of the solution on absorptions. The energy gap in gas phase as

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well as in the solvent phase is 5.508 eV and 5.411 eV, respectively. The calculated wavelengths (λmax), vertical excitation energies, oscillator strengths (f),

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dipole moments (μ), and excitation transition with spectral assignments for vacuum and the solvent environment are carried out as given in Table 3. The transition observed in the UV

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spectrum is π π*. In the gaseous phase in the LUMO, the charge is mainly accumulated on

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the ring R2 portions. Similarly, in HOMO and HOMO-1 the charge density is over the rings R2 and R3. However, in LUMO+1 it is over the ring R5 portion as shown in Fig. S2

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(Supplementary material). In solvent phase, the allowed dipole transition is at 261.32 nm (H

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L) with oscillator strength of 0.1363 and, in the gaseous phase, it is at 257.51 nm (H with oscillator strength of 0.0141. The H-1

L)

L transition is predicted at 252.05 nm with the

oscillator strength 0.0811 in the gas phase, while, H-1

L+1 transition at 290.14 nm is

predicted with oscillator strength 0.0240 in the solvent phase, respectively. The charge accumulation within the molecule in solvent phase is given in the Fig. S3 (Supplementary material).

4.6.

Vibrational spectrum 11

ACCEPTED MANUSCRIPT This CAD molecule has 46 atoms and hence gives 132 (3N-6; N the number of atoms) modes of vibrations. All the wavenumbers are both IR and Raman active. We have calculated these fundamental wavenumbers, their intensities and PED along with the internal coordinates obtained by HF and DFT with 6-311++G(d,p) basis set calculations. The wavenumbers predicted by HF method are larger than B3LPY due to the inclusion of electron

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correlation in the later. Since, the vibrational wavenumbers obtained from the DFT

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calculations are higher than the experimental wavenumbers, so the vibrational wavenumbers obtained from the DFT calculations were corrected by the wavenumber linear scaling (WLS)

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of Yoshida et.al. [40] by using the expression: υobs = (1.0087-0.0000163 υcal) υcal.

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The Raman scattering cross-sections, ∂σj/∂Ω, which is proportional to the Raman intensities may be calculated from the Raman scattering amplitude and predicted

  

 h   8 2 c j 

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 24  4    45

  4        0  j          hc j    1  exp     kT    

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 j

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wavenumbers for each normal modes using the relationship [41-43]:

  Sj  

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where, sj and υj are the scattering activities and the predicted wavenumbers (in cm-1), respectively of the jth normal mode, υo is the Raman exciting wavenumber (cm-1), and h, c

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and k are the universal constants. A comparison of the wavenumbers calculated by the DFT method shows very good agreement with the experimental values due to incorporation of electron correlation. The simulated and observed IR and Raman modes of the CAD molecule are given in Figs. 4 and 5, respectively. Out of several internal coordinates that may be present in the PED as given in Table 4, we have discussed here only some prominent modes:

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ACCEPTED MANUSCRIPT 4.6.1. Methoxy group vibration In a molecule containing methoxy group, the electronic charge is back donated from the lone pair atoms (oxygen) to the

* orbital of CH bond weakens the CH bonds. This

increases the CH bond resulting in the enhancement of the IR intensities in CH stretching [44, 45]. CH3 group has several modes associated with it, such as symmetric and asymmetric

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stretches, bends, rocks and torsions. There are two methyl groups (Me1 and Me2) connected to

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the same ring R5 as shown in the Fig. 1(b), forming methoxy groups. Asymmetric stretching

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modes associated to each Me1 and Me2 groups predicted in the range of 3000-2935 cm-1, were assigned in the weak IR and the strong Raman peaks. Symmetric stretching modes were

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predicted at 2902 and 2893 cm-1. Asymmetric deformations of Me1 and Me2 were assigned at 1493/1468 and 1485/1474cm-1 in the IR, and at 1491/1466 and 1480/1470 cm-1 in the Raman

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spectra, that is calculated at 1503/1473 and 1495/1481 cm-1, respectively. The calculated rocking vibrations at 1196/1166 cm-1 are in good agreements with 1186/1163 cm-1 in the IR

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and 1189/1164 cm-1 in the Raman peaks.

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4.6.2. Ring R1 vibrations

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Basically, six fundamental vibrational assignments can be associated with each CH2 moiety namely; symmetric and asymmetric stretch, deformation and rocking modes which

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belong to the polarized in-plane vibration. In addition to that, CH2 wagging and twisting would be expected to be depolarized out-of-plane symmetry [46]. The asymmetric stretching vibration of CH2 calculated at 2978 cm-1 and observed at 2997/3000 cm-1 in the IR/Raman spectrum. The symmetric stretching was observed at 2872/2868 cm-1 in the IR/Raman spectrum and calculated at 2886 cm-1 as shown in Table 4. Deformation mode of vibration predicted at 1537 cm-1 is in good agreement with the observed IR/Raman band at 1531/1533 cm-1. Highly mixed CH2 wagging, twisting and rocking vibrations were predicted at 1419,

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ACCEPTED MANUSCRIPT 1206 and 1138 cm-1, respectively.

4.6.3. Ring R2 vibrations The carbon-hydrogen stretching vibrations give rise to the weak bands in the region 3100-3000 cm−1 in all the aromatic compounds [47]. In the present case, the CH stretching

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modes were observed in this range with 100% contributions in PED. These bands are weak in

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the IR and medium strong in the Raman spectra. The in-plane deformation observed as the weak IR peak at 1495 cm-1 and the strong Raman peak at 1493 cm-1 and predicted at 1511

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cm-1. The out-of-plane deformations were calculated below 875 cm-1.

4.6.4. Ring R3 vibrations

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The CH stretching vibration predicted at 2766 cm-1 was assigned to IR/Raman peak at 2750/2753 cm-1. The rocking mode was observed at 1339/1345 cm-1 in the IR/Raman spectra.

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The mixed NC stretching vibrations were predicted at 1184 and 1159 cm-1 in the scaled DFT.

4.6.5. Ring R4 vibrations

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The CH2 asymmetric stretching vibrations predicted at 2958/2949 cm-1 were assigned to the strong Raman peaks at 2946/2940 cm-1 and the weak IR peaks at 2939/2937 cm-1. The

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calculated symmetric stretching vibrations for these modes are 2914 and 2784 cm-1. Their deformation, wagging, twisting and rocking vibrations are predicted at 1480/1472, 1377/1363, 1311/1274 and 1025 cm-1, respectively. The ring CC stretching vibration predicted at 1145 cm-1 is in good agreement with the observed IR/Raman peak at 1142/1140 cm-1.

4.6.6. Ring R5 vibrations

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ACCEPTED MANUSCRIPT The CH stretching vibrations associated with this ring were predicted at 3079 and 3040 cm-1. The CH in-plane bending was calculated at 1234 cm-1 corresponding to the observed peak at 1227 and 1233 cm-1 in the IR and Raman spectra, respectively. The out-ofplane deformation vibration of this mode was predicted at 924 and 803 cm-1. The calculated trigonal ring deformation mixed with the CO stretching vibration at 1248 cm-1 was found to

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be consistent with the recorded values at 1248/1241 cm-1 in the IR/Raman spectra. Another

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CO stretching mode vibration was predicted at 1293 cm-1. The CO in-plane deformation

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calculated at 651 cm-1 was assigned at 654/ 651 cm-1 in the IR/Raman spectra.

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4.7. Nonlinear optical (NLO) properties

Nonlinear optics deals with the interactions of various materials in applied

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electromagnetic fields to generate new field altered in phase, frequency, amplitude or other physical properties [48]. Some organic substances with

electronic system exhibit the largest

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known nonlinear coefficients and show promise for thin fabrication, allowing the enormous

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function and cost integrated electronic circuitry. The total dipole moment (μo), mean polarizability (∆α), the anisotropy of the

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polarizability (| |) and the total first hyperpolarizability (βo) using x, y, z components [39, 49] are calculated from the Gaussian 09 output and listed in the Table S5 (Supplementary

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material). In this study, the calculated values of μo , |

| and βo are 1.92 Debye, 32.76 x10-24

esu and 1200.87 x10-33 esu, respectively which are higher than those of urea (μo = 1.528 Debye, βo = 343.27 x 10-33 esu.) [50, 51]. These values are very much comparable with brucine/ strychnine (3.18/3.30 Debye, 39.47 x10-23/33.63 x10-23 esu and 221.97 x10-34/111.58 x10-34 esu) [13] and the p-NA [52]. From the above results, it appears that the title compound can be used as a good nonlinear material for the optical devices.

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ACCEPTED MANUSCRIPT 5. Conclusion Present work is mainly concentrated on the study of the wavenumber assignments of CAD by using IR and Raman data together with the quantum chemical calculations. Both the IR and Raman spectra were in good agreements with the modes calculated by the DFT. A comparison of the scaled wavenumbers obtained using DFT methods have better accuracy

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with the experimental modes than HF due to the fact that the former includes some of the

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electron correlation effects. The observed electronic spectra have some higher values (294

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and 286 nm) compared with the theoretical absorption data (258 and 252 nm) and the molecular orbital coefficient analysis suggests that the electronic transitions are assigned to π*. NBO analysis shows the stability and charge delocalization from various bonding to

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π

anti-bonding orbitals ( *) of the title compound. MEP studies suggest that the nitrogen and

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oxygen (of the methoxy groups) atoms are the most reactive sites. The reactivity descriptors also tell that O2 and O1 atoms are more prone to nucleophilic attack. The observed

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microscopic NLO properties suggest its potential use in the development of NLO materials. It

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is reported that the title compound possesses anti-fibrillatory and antioxidant activity as well as behaves as a potent inhibitor of platelet aggregation. To predict and confirm these types of

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activity theoretically, molecular docking studies will be performed which are very useful for

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the industrial and biologically active compounds.

Acknowledgments:

B.D. Joshi would like to thank the CNPq-TWAS for fellowship (CNPq-TWAS/PostDoc/2014/ FR number: 3240279899) to pursue Post-Doc study in UFC, Fortaleza, Brazil. A.S. thanks University Grants Commission (UGC), New Delhi for financial assistance under PDF for Women Scientist; grant no. F.15-1/2014-15/PDFWM-2014-15-GE-UTT-24257 (SAII). P.T. is thankful to DST, New Delhi for financial support under the Indo- Brasil project

16

ACCEPTED MANUSCRIPT (grant no. DST/INT/Brazil/P-10/2013).

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[2] S. Foster, J. Duke, A Field Guide to Medicinal Plants and Herbs of Eastern and Central

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G. Scalmani, V. Barone, B. Mennucci, G.A. Petersson, H. Nakatsuji, M. Caricato, X. Li, H.P. Hratchian, A.F. Izmzylov, J. Bloino, G. Zheng, J.L. Sonnenberg, M. Hada,

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Bearpark, J.J. Heyd, E. Brothers, K.N. Kudin, V.N. Staroverov, R. Kobayashi, J.

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Normand, A. Raghavachari, A. Rendell, J.C. Burant, S.S. Iyengar, J. Tomasi, M.Cossi, N. Rega, J.M. M illan, M. Klene, J.E. Knox, J.B. Cross, V. Bakken, C.

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Adamo, J. Jaramillo, R. Gomperts, R.E. Stratmann, O. Yazyev, A.J. Austin, R.Cammi, C. Pomelli, J.W. Ochterski, R.L. Martin, K. Morokuma, V.G. Zakrzewski,

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G.A. Voth, P. Salvador, J.J. Dannerberg, S. Dapprich, A.D. Daniels, J. Farkas, B. Foresman, J.V. Ortiz, J. Cioslowski, and D.J. Fox, GAUSSIAN 09, Revision, Gaussian, Inc., Wallingford CT, USA, 2009. [19] C. Lee, W. Yang, R.G. Parr, Phys. Rev. 37 (1988) 785-789. [20] A.D. Becke, J. Chem. Phys. 98 (1993) 5648-5652. [21] R.G. Parr, W. Yang, Density Functional Theory of Atoms and Molecules, Oxford, New York, 1989.

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ACCEPTED MANUSCRIPT [22] E.D. Glendering, A.E. Reed, J.E. Carpenter, F. Weinhold, NBO Version 3.1, TCI, University of Wisconsin, Madison, 1998. [23] G.A. Petersson, A. Bennett, T.G. Tensfeldt, M.A. Allaham, W.A. Shirley, J. Mantzaris, J. Chem. Phys. 89 (1988) 2193-2218. [24] G.A. Petersson, M.A. Allaham, J. Chem. Phys. 94 (1991) 6081-6090.

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[25] J.M.L. Martin, C. Van Aslenoy, Gar2ped, University of Antwerp, 1995.

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[26] P. Pulay, G. Fogarasi, F. Pang, J.E. Boggs, J. Am. Chem. Soc. 101 (1979) 2550-2560.

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[27] G. Fogarasi, X. Zhou, P.W. Taylor, P. Pulay, J. Am. Chem. Soc. 114 (1992) 81918201.

NU

[28] A. Frisch, A.B. Nielson, A.J. Holder, Gauss View User Manual, Gaussian Inc, Pittsburgh, P.A., 2000.

MA

[29] G.A. Zhurko, D.A. Zhurko, Chemcraft 2005, . [30] S. Miertuš, E. Scrocc, J. Tomasi, Chem. Phys. 55 (1981) 117-129.

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[31] S. Miertus, J. Tomasi, Chem. Phys. 65 (1982) 239-247.

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[32] M. Cossi, V. Barone, R. Cammi, J. Tomasi, Chem. Phys. Lett. 255 (1996) 327-335. [33] M.W. Wong, Chem. Phys. Lett. 256 (1996) 391-399.

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[34] A.P. Scott, L. Radom, J. Phys. Chem. 100 (1996) 16502-16513. [35] F. Weinhold, C.R. Landis, Valency, and bonding: A Natural Bond Orbital Donor-

AC

Acceptor Perspective, Cambridge University Press, New York, 2005. [36] R.G. Parr, L. Szentpály, S. Liu, J. Am. Chem., Soc. 121 (1999) 1922-1924. [37] R.G. Parr, R.G. Pearson, J. Am. Chem. Soc., 105 (1983) 7512-7516. [38] P. Geerlings, F. De Proft, W. Langenaeker, Chem. Rev., 103 (2003) 1793-1874. [39] P.K. Chattaraj, S. Giri, J. Phys. Chem. A, 111 (2007) 11116-11121. [40] H. Yoshida, K. Takeda, J. Okamura, A. Ehara, H. Matsurra, J. Phys. Chem. A 106 (2002) 3580-3586.

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ACCEPTED MANUSCRIPT [41] P. Pulay, G. Fogarasi, G. Pongor, J.E. Boggs, A. Vargha, J. Am. Chem. Soc., 105 (1983) 7037-7047. [42] G.A. Guirgis, P. Klaboe, S. Shen, D.L. Powell, A. Gruodis, V. Aleksa, C.J. Nielsen, J. Tao, C. Zheng, J.R. Durig, J. Raman Spectrosc. 34 (2003) 322-336. [43] P.L. Polavarapu, J. Phys. Chem. 94 (1990) 8106-8112.

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sixth ed., John Wiley & Sons Inc., New York, 2003.

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[44] R.M. Silverstein, F.X. Webster, Spectroscopic Identification of Organic Compounds,

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[45] P. Agarwal, N. Choudhary, A. Gupta, P. Tandon, Vibrational Spectrosc. 64 (2013) 134-147.

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[46] B.D. Joshi, A. Srivastava, P. Tandona, S. Jain, Spectrochim. Acta A 82 (2011) 270278.

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[47] B. Smith, Infrared Spectral Interpretation. A Systematic Approach, CRC Press, Washington, DC, 1999.

D

[48] D.J. Williams, Angew. Chem. Int. Ed. Engl. 23 (1984) 690-703.

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[49] H. Alyar, Z. Kantarci, M. Bahat, E. Kasap, J. Mol. Struct. 834-836 (2007) 516-520. [50] N. Sundaraganesan, J. Karpagam, S. Sebastian, J.P. Cornard, Spectrochim. Acta A 73

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(2009) 11–19.

[51] K. Chandramohan, K. Ravikumar, J. Chem. Cryst. 29 (1999) 121–125.

AC

[52] L. Jensen, P.D. Thvan, J. Chem. Phys., 123 (2005) 074307-7.

20

ACCEPTED MANUSCRIPT Figure captions Fig. 1(a). Chemical structure of CAD. Fig. 1(b). Optimized structure of CAD. Fig. 2. MEP mapped (from -4.389e-2 to +4.389e-2). Fig. 3. UV-Vis spectra taken in ethanol.

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Fig. 4. Comparison between observed and the calculated FT-IR spectra.

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Fig. 5. Comparison between observed and the calculated FT-Raman spectra.

Fig. S2. HOMO-LUMO plot in the gas phase.

AC

CE

PT E

D

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Fig. S3. HOMO-LUMO plot in the solvent phase.

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Fig. S1. Overlapping between experimental (purple) and the optimized molecular structures.

21

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PT E

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SC

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ACCEPTED MANUSCRIPT

22

Fig. 1

AC

CE

PT E

D

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PT

ACCEPTED MANUSCRIPT

23

Fig. 2

AC

CE

PT E

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ACCEPTED MANUSCRIPT

24

Fig. 3

AC

CE

PT E

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25

Fig. 4

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ACCEPTED MANUSCRIPT

AC

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Fig. 5

26

ACCEPTED MANUSCRIPT Table 1 Second Order Perturbation Theory Analysis of Fock Matrix.

LP(2)O1

Acceptor NBO(j)

1.86493

1.86334

E(2)a kcal/mol

ED/e

[E(j)-E(i)]b

[Fi,j]c

au

au

*C17 – C18

0.36546

24.98

0.36

0.090

*C1 – H1

0.03904

6.29

0.68

0.060

*C2 – C3

0.36557

25.28

0.36

0.090

*C1 – H2

0.03904

6.26

0.68

0.060

0.39

0.056

1.90851

*C8 – C9

0.37837

8.71

LP(2)O4

1.85085

*C10 – C11

0.40903

27.78

0.34

0.094

*C20 – H19

0.01957

5.75

0.69

0.058

*C6 – H6

0.03722

8.51

0.65

0.068

*C7 – H8

0.03865

0.65

0.067

0.02870

6.17

1.01

0.071

0.02884

6.37

1.01

0.072

1.87519

1.9644

*O1 – C18

C3 – C4

1.96576

*O2 – C2

C17 – C18

1.97090

*C2 – C18

0.03844

5.15

1.29

0.073

C2 – C18

1.97304

*C2 – C3

0.36557

5.08

1.29

0.072

C4 – C16

1.69172

*C17– C18

0.36546

18.46

0.27

0.064

*C2 – C3

0.36557

18.09

0.27

0.064

* C8 – C9

0.37837

21.56

0.28

0.07

*C10 – C11

0.40903

19.44

0.27

0.066

*C12 – C13

0.36307

19.33

0.30

0.068

*C10 – C11

0.40903

21.31

0.28

0.070

*C4 – C16

0.34877

17.72

0.32

0.068

*C2 – C3

0.36557

19.59

0.30

0.070

*C4 – C16

0.34877

18.38

0.32

0.069

*C17– C18

0.36546

19.56

0.30

0.069

*C12 – C13

0.36307

19.48

0.31

0.070

*C8 – C9

0.37837

17.13

0.30

0.065

*C4 – C16

0.34877

137.61

0.02

0.080

C17 – C18

C2 – C3

C10 – C11

*C17– C18

D

PT E

CE

C8 – C9

1.67477

1.67004

AC

C12 – C13

MA

8.39

C16 – C17

NU

LP(1)N1

SC

LP(2)O3

RI

LP(2)O2

ED/e

PT

Donor NBO(i)

1.71465

1.71267

1.68223

0.36546

27

ACCEPTED MANUSCRIPT *C2 – C3

0.36557

*C4 – C16

0.34877

141.91

0.02

0.08

*C10 – C11

0.40903

*C12 – C13

0.36307

159.12

0.02

0.081

*C8 – C9

0.37837

228.59

0.01

0.082

AC

CE

PT E

D

MA

NU

SC

RI

PT

Energy E(2) ≥ 5 kcal mol-1 is assigned. a (2) E means energy of hyper conjugative interaction (stabilization energy). b Energy difference between donor and acceptor i and j NBO orbitals. c F(i, j) is the Fock matrix element between i and j NBO orbitals

28

ACCEPTED MANUSCRIPT Table 2 Atomic charges (in esu), Fukui functions (f+k,f--k); Local softness (s+k,s-k)); and local electrophilicity indices (ω+k, ω-k)); in eV for atomic sites, using Hirshfeld population analysis at B3LYP/6-31G(d,p) level. Fukui functions

Local softness

Local electrophilicity indices

qN-1

f+k

f--k

s+k

s-k

ω+k

ω -k

1 O

-0.165488

-0.122057

-0.180717

0.043431

0.015229

0.059801

0.020969

0.058922

0.020661

2 O

-0.164636

-0.114692

-0.185035

0.049944

0.020399

0.068769

0.028088

0.067759

0.027675

3 O

-0.169553

-0.144161

-0.176066

0.025392

0.006513

0.034963

0.008968

0.034449

0.008836

4 O

-0.148781

-0.107017

-0.150034

0.041764

0.001253

0.057506

0.001725

0.056661

0.001700

1 N

-0.120830

-0.083205

-0.121785

0.037625

0.000955

0.051807

0.001315

0.051046

0.001296

1 C

0.233609

0.302269

0.167463

0.068660

0.066146

0.094539

0.091078

0.093150

0.089740

2 C

0.052989

0.092700

0.009552

0.039711

0.043437

0.054679

0.059809

0.053876

0.058931

3C

-0.008032

0.038037

-0.116305

0.046069

0.108273

0.063433

0.149083

0.062501

0.146893

4 C

-0.015226

0.019149

-0.033162

0.034375

0.017936

0.047332

0.024696

0.046636

0.024334

5 C

0.018291

0.063392

-0.022792

0.045101

0.041083

0.062100

0.056568

0.061188

0.055737

6 C

0.052459

0.097040

0.010711

0.044581

0.041748

0.061384

0.057484

0.060483

0.056639

7 C

0.059514

0.100245

0.003940

0.040731

0.055574

0.056083

0.076521

0.055259

0.075397

8 C

-0.020745

-0.013799

-0.045168

0.006946

0.024423

0.009564

0.033628

0.009424

0.033134

9 C

0.052690

0.089556

0.005925

0.036866

0.046765

0.050761

0.064392

0.050016

0.063446

10 C

0.059311

0.096577

0.035486

0.037266

0.023825

0.051312

0.032805

0.050558

0.032323

11 C

-0.034798

0.007966

-0.105321

0.042764

0.070523

0.058882

0.097104

0.058018

0.095678

12 C

-0.014170

0.044029

-0.106163

0.058199

0.091993

0.080135

0.126667

0.078958

0.124806

13 C

-0.020859

0.004017

-0.032678

0.024876

0.011819

0.034252

0.016274

0.033749

0.016035

14 C

0.016552

0.057367

-0.018815

0.040815

0.035367

0.056199

0.048697

0.055373

0.047982

15 C

0.048796

0.089400

0.024872

0.040604

0.023924

0.055908

0.032941

0.055087

0.032457

16 C

-0.017853

0.011469

-0.040174

0.029322

0.022321

0.040374

0.030734

0.039781

0.030283

17 C

-0.007228

0.023172

-0.105810

0.0304

0.098582

0.041858

0.135739

0.041243

0.133745

18 C

0.052136

0.084925

0.019574

0.032789

0.032562

0.045148

0.044835

0.044485

0.044177

19 C

0.118028

0.162462

0.051688

0.044434

0.06634

0.061182

0.091345

0.060283

0.090003

20 C

0.143607

0.200949

0.088600

0.057342

0.055007

0.078955

0.075740

0.077795

0.074628

AC

D

MA

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qN+1

CE

qN

RI

Hirshfeld atomic charges

PT E

Atom no.

29

AC

CE

PT E

D

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ACCEPTED MANUSCRIPT

30

ACCEPTED MANUSCRIPT Table 3 Electronic transitions, absorption wavelength λmax (nm), excitation energy (eV), oscillator strengths (f), frontier orbital energies (eV) and dipole moment (Debye). λmax

Excitation transition Solvent phase

H-1

3

H

L+1

H

4

H

L+2

5

H

L+3

6

H-1

L+2

H-1

7

H-1

L+3

8

H-2

L+3

Solvent phase

Gas phase

Solvent phase

Gas

Solvent

0.0141

0.1367

L

294

257.51

261.32

4.8148

4.7446

L+1

286

252.05

250.14

4.9191

4.9566

0.0811

0.0240

L+1

247.52

245.76

5.0091

5.0450

0.0118

0.0104

H

L+2

235.08

234.16

5.2740

0.0525

0.0369

H

L+3

228.96

230.84

L+2

219.71

222.06

H-1

L+3

216.06

218.62

H-4

L+1

210.84

200.35

H

L

Gas phase

H-1

ELUMO

Gas

-5.487369

Solvent

-5.534935

5.2949

5.4150

5.3709

0.0352

0.0964

5.6431

5.5833

0.0507

0.0495

5.7384

5.6712

0.0182

0.0229

5.8806

6.1884

0.0536

0.0967

E

µ (D)

0.020300

5.507669

1.8635

-0.124057

5.410878

2.0921

AC

CE

PT E

D

EHOMO

PT

2

L

Calculated

RI

H

Calculated

Oscillatory strength (f) Calculated

SC

1

Expt

NU

Gas phase

E (eV)

MA

Excited states

31

Transition type/ assignments

π

π*

ACCEPTED MANUSCRIPT Table 4 Comparison between calculated and observed (FT-IR and micro-Raman) wavenumbers (cm-1) and the PED distribution of CAD. Calculated Unscaled

Observed Scaled

IR

Potential energy distribution (PED %)

Raman

HF

DFT

HF

3220

3367

3079

3212

3065

3069

R5[υ(CH)](99)

3216

3359

3075

3204

3038

3067

R2[υ(CH)](98)

3206

3344

3067

3191

3036

3038

R2[υ(CH)](98)

3177

3316

3040

3166

-

3025

R5[υ(CH)](99)

3148

3299

3014

3151

3001

3003

Me2[υa(CH3)](100)

3145

3279

3011

3133

2999

3002

Me1[υa(CH3)](99)

3109

3278

2978

3132

2997

3000

R1[υa(CH2)](99)

3098

3246

2969

3102

-

-

3086

3237

2958

3094

2939

2946

3077

3225

2949

3083

2937

3075

3222

2948

3081

2930

3074

3209

2947

3069

3069

3202

2942

3038

3189

2914

3032

3178

2908

3025

3166

2902

3015

3166

2893

3008

3162

2918

NU

SC

RI

PT

DFT

Me1[υa(CH3)](99)

3938

Me2[υa(CH3)](100)

2928

2930

R3[υa(CH2)](93)

3063

2926

2928

R3[υa(CH2)](98)

3051

2899

2897

R4[υs(CH2)](99)

3041

2897

2895

R3[υs(CH2)](97)

3030

2887

-

Me1[υs(CH3)](99)

3030

2885

2878

Me2[υs(CH3)](99)

2886

3027

2872

2868

R1[υs(CH2)](99)

3078

2805

2950

-

2805

R3[υs(CH2)](95)

2895

3068

2784

2942

2752

2755

R4[υs(CH2)](95)

2875

3046

2766

2921

2750

2753

R3[υ(CH)](94)+υa(CH2)(5)]

1677

1822

1646

1783

1622

1626

R2[υ(CC)(57)+δa(11)+δin(CH](5)]+R1[δring](8)

1674

1806

1642

1768

1618

1625

R2[υ(CC)(52)+[δ’a](11) +R1[υ(CC)](23)

1660

1798

1629

1760

1605

1607

R5[υ(CC)(51) +δa(11)+δin(CH)(8)]

1632

1769

1603

1733

1584

1586

R5[υ(CC)(51)+δ’a(10)+δin(CH)(6)]+R4[υ(CC)]

PT E

D

R4[υa(CH2)](99)

AC

2940

CE

MA

R4[υa(CH2)](96)

32

ACCEPTED MANUSCRIPT (21) 1680

1537

1649

1531

1533

R1[δ(CH2)](84)

1538

1662

1513

1631

1506

1501

R5[υ(CC)(32)+δin(CH)(26)]+R4[υ(CC)](15)+δa [Me2(CH3)](8)

1536

1655

1511

1625

1495

1493

R2[δin(CH)(29)+υ(CC)](24)]+R1[υ(CC)(19)+δ CH2](12)+υ(CO)(5)]

1527

1637

1503

1608

1493

1491

Me1(CH3)[(δa(56)+δ’(32)+ρ’(9)]

1522

1634

1497

1605

1491

1490

R3[δ(CH2)](67)+R4[δ(CH2)](13)+δ[Me2(CH3)] (5)

1519

1631

1495

1601

1485

1480

Me2(CH3)[δa(77)+ρ’(8)]+R3[δ(CH2)](6)

1505

1621

1481

1592

1474

1470

Me2(CH3)[δ’a(88)+ρ(5)]

1504

1621

1480

1592

1470

1468

R4[δ(CH2)](23)+δa[Me1(CH3)](21)+R3[δ(CH2) ](12)+R5[υ(CC)](8)+R5[υ(CO)](6)

1497

1617

1473

1588

1468

1466

Me1(CH3)[ δ’a(55)+δa(33)+ρ(7)]

1495

1611

1472

1583

1466

1461

1487

1604

1464

1576

1458

1485

1603

1462

1575

1456

1480

1600

1457

1573

1454

1473

1593

1451

1467

1587

1444

1440

1565

1419

1430

1550

1427

NU

SC

RI

PT

1563

MA

R4[δ(CH2)](48)+δs[Me1(CH3)](20)+δs[Me2(CH 3)](6)+R3[δ(CH2)](5) R3[δ(CH2)](88)

1455

δs[Me2(CH3)](66)+R4[δ(CH2)](15)

1453

R4[δ(CH2)](68)+δs[Me2(CH3)](10)+δs[Me1(CH 3)](7)

1450

1441

R2[υ(CC)](22)+R3[υ(CC)(10)+δtrig(5)+δa(5)]+ R4[δ(CH2)](6)+R1[ω(CH2)](6)

1559

1443

1439

δs[Me1(CH3)](34)+R5[υ(CC)](18)+R4[υ(CC)]( 6)

1539

1414

1426

R1[ω(CH2)](42)+R3[ω(CH2)](20)+R4[ω(CH2)] (8)

1409

1524

1408

1410

R1[ω(CH2)](36)+R3[ω(CH2)](24)+R4[ω(CH2)] (8)

1534

1406

1509

1406

1407

R2[υ(CC)](56)+R1[υ(CO)](5)

1396

1510

1377

1486

1358

1357

R4[ω(CH2)](31)+R3[CH(ρ’)(CH(20)+ω(CH2)( 8)]

1383

1497

1363

1474

1356

1355

R4[ω(CH2)](35)+υ(CC)(13)]+R3[ρ(CH)(13)+ω (CH2)](11)]

1371

1493

1352

1469

1348

1349

R3[(ω(40)+γ(10))CH2+υ(CC)(13)]

1363

1471

1344

1449

1339

1345

R3[ρ(CH)(40)+(ω(CH2)(19)+γ(CH2)(5)]

AC

1565

CE

PT E

D

1457

33

1329

1423

1325

1326

R5[υ(CC)](50)+R3[ρ’(CH)](9)+R4[υ(CC)](7)

1328

1436

1311

1415

1304

1303

R4[γ(24)+(5)](CH2)+R3[ρ’(CH)](17)+υ(N5C3 3)(5)+γ(CH2)(5)]+R5[υ(CC)](8)+δin(CH)(5)]

1317

1426

1300

1405

1300

1295

R4[υ(CC)](16)+υ(NC)(6)]+R5[υ(CC)](16)+R3[ γ(CH2)](14)

1310

1384

1293

1365

1281

1283

R5[υ(CO)(28)+δin(CH)(13)+υ(CC)(10)+R4[ω( CH2)](6)+R3[γ(CH2)](5)

1290

1378

1274

1359

1273

1277

R4[γ(CH2)](22)+R1[υ(CO)](11)+υ(CC)(9)]+R2 [υ(CC)(19)]+R3[γ(CH2)](7)

1270

1366

1254

1348

1250

1247

R2[δin(CH)](27)+R3[γ(CH2)(10)+δtrig(9)]+R4[γ (CH2)(10)+υ(NC)(5)]

1263

1352

1248

1334

1248

1241

R5[δtrig(24)+υ(CO)(23)]+R4[ω(CH2)(8)+υ(CC) ](7)

1256

1349

1241

1331

1229

1239

R4[γ(CH2)](25)+R2[υ(CC)(22)+δin(CH)(6)]+R 1[υ(CC)(7)+υ(CO)(9)]

1248

1329

1234

1311

1227

1233

1236

1327

1222

1309

1213

1225

1324

1212

1307

1211

1219

1314

1206

1297

-

1198

R1[γ(CH2)](32)+R4[γ(CH2)(21)+R2[δin(CH)(7) ]+R2[δin(CH)](6)

1213

1310

1200

1293

-

1196

ρ’[Me2(CH3)](29)+R5[δin(CH)(15)+δtrig(7)]+υ( CC)(6)]+R4[υ(CC)](5)+R1[γ(CH2)](5)

1210

1307

1196

1291

1186

1189

ρ’[Me1(CH3)](51)+ρ’[Me2(CH3)](12)

1202

1298

1189

1282

1184

1187

R2[δtrig](24)+R1[γ(CH2)](18)+R3[υ(CC)](13)+ R4[γ(CH2)](5)

1196

1285

1184

1269

1182

1185

R3[υ(NC)](30)+R4[γ(CH2)](6)+R3[υ(CC)](6)+ R5[υ(CC)](5)+ρ’[Me2(CH3)](5)

1193

1279

1180

1264

1180

1183

ρ’[Me2(CH3)](15)+R5[δin(CH)(15)+υ(CC)(7)]+ R3[υ(NC)](13)

1178

1278

1166

1263

1163

1164

[ρ(69)+ρ’(22)] Me2(CH3)

1177

1258

1165

1243

1162

1162

[ρ(73)+ρ’(20)] Me1(CH3)

1171

1252

1159

1237

1159

1160

R3[υ(NC)](14)+υ(CC)(11)]+R2[δin(CH)](21)+ R2[υ(CC)](20)

CE

AC

NU

SC

RI

PT

1444

PT E

1347

D

ACCEPTED MANUSCRIPT

MA

R5[δin(CH)(21)+υ(CC)(16)]+R4[ω(CH2)](16)+ υ(CC)(6)]+R3[ρ’(CH)](10)

1216

R2[δtrig(12)+δin(CH)(13)]+R1[γ(CH2)](22)+R3[ γ(CH2)](14)

1212

R3[γ(CH2)](30)+R4[γ(CH2)](23)+R1[γ(CH2)](1 0)

34

ACCEPTED MANUSCRIPT 1222

1150

1208

1140

1146

R4[υ(NC)](33)+R3[γ(CH2)(11)+υ(NC)(5)]+R2 [δtrig](11)

1149

1210

1138

1196

1130

1131

R1[ρ(CH2](88)

1121

1193

1110

1180

1082

1083

υ(C20O)(35)+R5[δin(CH)](8)+R4[υ(CC)](7)+υ (C19O)(6)

1099

1187

1088

1174

1080

1081

R3[ρ(CH2)](17)+υ(C19O)(13)+R4[υ(CC)](8)+ R3[puck](6)+υ(C20O)(6)

1088

1182

1078

1170

1078

1079

R3[ρ(CH2)(18)+υ(CC)(8)+puck(8)]+υ(C19O)(8 )+R4[υ(CC)](7)+υ(C20O)(6)

1080

1167

1070

1155

1051

1065

R1[υ(CO)](21)+R3[υ(CC)](20)+R4[υ(CC)](9)+ υ(C19O)(8)+υ(C20O)(6)+R2[δa](6)

1073

1161

1063

1149

1049

1052

R1[υ(CO)(67)+δring (11)+υ(CC)(5)]

1054

1144

1045

1133

1042

1040

R4[υ(CC)(28)+υ(NC)(6)]+R3[ρ(CH2)(12)+ρ(C H2)(8)+υ(NC)(6)]

1034

1128

1025

1117

1018

1021

R4[ρ(CH2)(40)+puck(14)]+R3[υ(CC)](13)

1016

1120

1008

1110

993

1007

991

1104

983

1093

979

978

1074

971

1065

957

973

1050

966

1041

955

930

1043

924

921

1002

915

901

997

895

876

976

874

NU

SC

RI

PT

1162

MA

υ(C19O)(27)+R4[ρ(CH2)(16)+δtrig(7)]+R3[ρ(C H2)](5) R4[ρ(CH2)(38)+R3[υ(CC)](6)+υ(C20O)(5)

959

R3[υ(CC)(14)+ρ(CH2)(8)]+υ(C19O)(11)+R4[υ (CC)](9)+R5[δa](6)+υ(C20O)(6)

PT E

D

980

957

R1[υ(CO)](73)+R1[δ’ring](6)

-

919

R5[oop(CH)(75)+puck(7)]

994

910

912

R3[ρ(CH2)(22)+δtrig(8)]+R4[δtrig](6)+R5[oop(C H)](9)

990

883

884

R4[υ(CC)(11)+ρ(CH2)(9)]+R2[oop(CH)](16)+ R3[ρ(CH2)(12)+υ(NC)](5)

871

969

881

874

R2[oop(CH)](73)+R2[τ’](5)

966

870

959

860

863

R2[oop(CH)](23)+R2[puck](7)+R5[δ’a](6)+R1 [υ(CO)] (5)

867

938

863

932

858

861

R2[oop(CH)](66)+R2[puck](11)

834

911

830

905

820

824

R1[υ(CO)(22)+υ(CC)(13)+δring(5)]+R2[υ(CC)( 10)+δ’a(9)]

807

896

803

891

804

805

R5[oop(CH)(73)+puck(10)+τ(6)+oop(C9O)(5)]

781

865

778

861

775

776

R5[puck(25)+oop(C9O)(17)+oop(C10O)(6)+R 3[υ(NC)(13)+ρ(CH2)(6)]

AC

CE

1035

35

ACCEPTED MANUSCRIPT 840

758

835

767

755

R5[puck(29)+oop(C9O)(17)+oop(C10O)(8)+oo p(CH)(5)]

754

818

751

814

750

753

R1[δ’ring](16)+R3[υ(CC)](10)+R5[δtrig](6)+R2[ υ(CC)](6)

746

812

743

809

748

751

R2[δtrig](17)+R1[δ’ring](16)+R5[δtrig](10)

735

805

733

801

-

720

R2[puck](47)+R1[δring](13)+R3[puck](7)+τ(C3 5C12)(5)

722

797

720

793

717

718

R1[δring(37)+υ(CO)(6)]+R2[puck(20)+δ’a(11)]

716

765

714

763

706

708

R5[puck(12)+υ(CC)(10)+υ(CO)(6)]+R4[υ(CC) ](15)

689

759

687

756

687

689

R2[τ(24)+puck(6)]+R1[δ’ring(12)+τ(8)]+R3[δtrig ](13)

669

728

667

725

667

660

R2[τ(23)+δa(11)]+R3[puck](10)

652

700

651

698

654

651

R5[δin(CO)(21)+puck(7)+υ(CC)(6)+δ’a(5)]+R4 [δ’a(9)+δtrig(6)]+δ(C10C20O)(7)

615

674

614

672

619

610

566

625

566

624

559

558

605

558

605

557

532

571

532

571

530

518

556

518

510

552

511

501

539

446

NU

SC

RI

PT

761

MA

R5[τ(18)+puck(14)+oop(CO)(13)]+R4[τ(9)+pu ck(8)] R5[τ’(14)+oop(CO)(11)+puck(5)]+τ(N1C15)(7 )+R3[δ’a](6)+R4[δ’a](5)

558

R5[oop(CO)(19)+τ’(12)+τ(8)+R2[δ’a](7)

515

516

R3[δ’a(26)+δa(10)]+R5[δin(CO)](6)+τ(N1C15)( 5)

552

509

510

R4[δ’a(17)+δa(9)+ρ(CH2)(5)]+R5[δ’a(12)+τ’(8) +δa(5)]

501

539

507

505

R5[δa(18)+τ’(5)]+δ(C10C20O)](12)+R3[δa](7)

484

447

485

442

440

R2[τ’(27)+δa(24)]+τ(C4C16)(8)+R5[δa](5)+R3[ puck](5)

432

467

432

468

431

427

R2[τ’(31)+δa(23)]+τ(C4C16)(17)+τ(C2C18)(8)

407

440

407

440

405

410

R4[δa(20)+τ(5)]+R5[τ’](15)+δ(C10C20O)](13) +δ(C9C19O)](8)

388

424

389

425

-

388

R3[δ’a(15)+δa(15)+puck(7)]+τ(N1C15)(10)

381

415

382

416

-

383

τ(C2C18)(33)+R5[τ’](8)+R2[τ’](8)+R5[oop(C1 0O)](6)

373

400

374

401

-

375

τ(C2C18)(19)+R5[τ’(11)+oop(C10O)(8)]+R4[p

PT E

R5[δ’a(11)+τ’(9)+δa(5)+oop(CO)(5)]+R3[δa](1 2)+R2[δ’a](8)+R4[puck](5)

AC

531

CE

D

560

556

36

ACCEPTED MANUSCRIPT

374

346

375

-

340

R5[δin(C9O)](11)+δ(C10C20O)](9)+R4[δa](8)+ τ(C8C13)(5)

339

366

340

367

-

338

τ(C8C13)(31)+δ(C9C19O)](12)+R4[τ](9)+R4[τ ’](8)+R5[τ](6)+R5[puck](5)

300

333

301

334

-

292

τ(N1C15)(20)+R5[δin(C9O)](12)+τ(C2C18)(10 )+R3[τ](6)+R1[τ’](5)

286

312

287

313

-

288

τ(C2C18)(18)+R3[puck](18)+R2[puck](12)+R 3[τ](12)+R1[τ](9)+R4[puck](5)

268

292

269

293

-

269

R3[puck(12)+τ’(12)+δ’a(9)]+τ(C2C18)(7)+τ(N 1C15)(7)+R1[τ’](6)

254

270

255

271

-

248

R4[τ’(15)+puck(7)]+R5[oop(C9O)](12)+τ(C20 O)(7)+R4[τ](6)+R5[τ’](5)+δ(C9C19O)](5)

242

256

243

258

-

244

τ(C20O)(67)+τ(C8C13)(6)+R4[puck](5)

222

243

223

244

-

207

R4[puck(12)+τ’(5)]+R2[τ](9)+τ(C8C13)(9)+R1 [τ](8)+R3[τ](6)+R3[δa](5)

195

211

196

213

-

201

188

204

189

205

-

181

191

182

192

148

159

148

141

150

141

125

140

126

111

128

89

PT E

-

NU

SC

RI

PT

345

D

uck](12)

MA

R5[δin(C10O)(17)+oop(C9O)(14))]+R2[τ](8)+δ (C10C20O)](8)+R1[τ](5)+δ(C9C19O)](5) τ(N1C15)(27)+R1[τ’(19)+τ(8)]+R3[τ](7)+τ(C4 C16)(6) +τ(C2C18)(5)

190

180

R4[δa](17)+R5[oop(C9O)(9)+δin(C10O)(6)]+τ( C19O)(8)+R4[τ](5)+R1[τ](5)

-

-

τ(C19O)(26)+τ(N1C15)(13)+τ(C8C13)(9)+R4[ puck](8)

151

-

140

R1[τ’](34)+R5[τ](12)+R4[puck(9)+τ(9)]+τ(C8 C13)(11)+τ(N1C15)(6)

141

-

122

R3[τ](17)+τ(N1C15)(16)+R1[τ](14)+τ(C4C16) (6)+R4[τ](6)+τ(C2C18)(5)+τ(C19O)(5)+R5[τ]( 5)+R2[τ](5)

112

129

-

109

R1[τ’](43)+τ(C8C13)(8)+τ(C19O)(6)

115

90

116

-

107

R3[τ’(13)+puck(6)]+τ(C10O)(12)+τ(C4C16)(9) +R4[τ](11)+R5[τ’](8)+τ(C2C18)(6)+R2[τ](5)+ τ(N1C15)(5)

82

104

83

104

-

-

τ(C9O)(59)+δ(C9C19O)](8)+τ(C19O)(6)+R5[δ in(C9O)](5)

74

71

75

71

-

-

τ(C10O)(37)+τ(C20O)(14)+τ(C9O)(9)+R4[τ’]( 8)+R3[τ’](5

AC

CE

160

37

ACCEPTED MANUSCRIPT 61

66

62

67

-

-

τ(N1C15)(31)+R3[puck](17)+R2[τ](9)+R3[τ](1 1)+τ(C10O)(7)+τ(C8C13)(6)

39

41

39

42

-

-

τ(N1C15)(41)+R4[τ](20)+R3[τ’(12)+τ(5)]

28

31

28

31

-

-

R4[τ’](30)+R3[τ](14)+τ(C4C16)(14)+τ(C8C13 )(14)+τ(N1C15)(14)

AC

CE

PT E

D

MA

NU

SC

RI

PT

Proposed assignments and potential energy distribution (PED) for vibrational normal modes. Types of vibration: ν, stretching; δ, deformation (bending), scissoring; oop, out-of-plane bending; ω, wagging; γ, twisting; ρ, rocking; τ, torsion; a Potential energy distribution (contribution ≥ 5).

38

D

MA

NU

SC

RI

PT

ACCEPTED MANUSCRIPT

AC

CE

PT E

Graphical abstract

39

ACCEPTED MANUSCRIPT Highlights ► FT-IR and FT-Raman spectra were recorded and compared with the theoretical results. ► The theoretical calculations were made using HF/DFT/B3LYP/6-311++G(d,p) method. ► The absorption spectrum has been compared with the experimental UV-Vis data. ► MEP surface have been plotted and reactivity descriptors have also been given.

AC

CE

PT E

D

MA

NU

SC

RI

PT

► The nonlinear optical properties have been calculated.

40