Tin ( IV ) Complexes of Schiff Base Derived from Amino Acid : Synthesis and Characteristic Spectral Studies

A new series of tin(IV) complexes of general formula [Sn(L-1)(Opr)2] (1), [Sn(HL-1)2(Opr )2] (2), [Sn(L-2)(Opr )2] (3), [Sn(HL2)2(Opr )2] (4), (L is dianion of Schiff bases derived from the condensation of 2-hydroxy-1-naphthaldehyde with glycine (L-1) and LLββ-alanine (L-2)) was synthesized by reaction of tin(IV) tetraisopropoxide with the ligands, in appropriate stoichiometric ratios (1 : 1 and 1 : 2). is would result in the replacement of the isopropoxide group from the tin(IV) tetraisopropoxide and hydrogen(s) from ligand with the azeotropical removal of isopropanol. An attempt has been made to prove the structure of the resulting complexes on the basis of elemental analysis, IR, H nuclear magnetic resonance. e binding site of the ligand was identi�ed by IR spectroscopic measurement. In these complexes, the tin(IV) centre is bonded to oxygen atom of the hydroxyl or carboxylate group. e spectra data suggest that the carboxylate group is coordinated to tin(IV) centre in monodentate manner.


Introduction
e interest in tin chemistry has attracted considerable attention due to its remarkable industrial, medicinal, and agricultural applications [1][2][3][4], and the coordination behavior of tin metal with the biological active ligand has been studied since the last decade due to its wide applications in several areas such as antitumour [5], antiviral [6], bactericides, fungicides [7], marine antifouling paints, surface disinfectants, wood preservatives [8], and many more.Schiff base is an important class of ligand in coordination chemistry and has important and vast biological application in different �elds [9].e interaction of tin metal to the organic group via O-Sn and N-Sn bonds has aroused considerable interest in several research �elds.Prompted by these facts, we have synthesized some tin(IV) complexes with Schiff bases and illustrated their geometrical structure by using spectral analysis.

Experimental
2.1.Materials and Methods.All the reagents, namely, tin (Merck), 2-hydroxynaphthaldehyde (Aldrich), were used as received.All the chemicals and solvents used were dried and puri�ed by standard methods, and moisture was excluded from the glass apparatus using CaCl 2 drying tubes.e melting points were determined in open capillaries with electronic melting point apparatus.C, H, and N analyses of these compounds were carried out in a VarioEL, CHNS elemental analyzer.e tin content in the synthesized compounds was determined gravimetrically as SnO 2 .Infrared spectra of the solid compounds were recorded on a Perkin-Elmer 1600 series FT-IR spectrophotometer in the range 4000-400 cm − from KBr discs. 1 H NMR spectra were recorded on a Bruker DRX 300 (300 MHz FT NMR) spectrometer at the Central Drug Research Institute, Lucknow, India, using CDCl 3 as a solvent and TMS as the internal standard.

Synthesis of Schiff
Bases.Schiff bases were prepared by condensation of hot aqueous (25 mL) solution of glycine or alanine (.013 mole) and 2-hydroxy 1-naphthaldehyde (.013 mole), dissolved in ethanol (50 mL).e reaction mixture was re�uxed for about 2 h, and yellow brown polycrystalline precipitate was obtained aer standing overnight.It was puri�ed by repeated washing with aqueous-ethanol (1 : 2) and dried in vacuum over fused CaCl 2 (Scheme 1) [10].

Synthesis of Complexes
. e synthetic route used to synthesize complexes is outlined in Scheme 2. In the �rst step, SnCl 4 was prepared by the action of chlorine gas on pure tin metal in a specially designed apparatus (bubbler).A pale yellow liquid of SnCl 4 thus obtained was puri�ed by distillation.e tin(IV) isopropoxide was synthesized by using literature method [11].A solution of tin(IV) tetrachloride (2.471 gm, 0.0095 mole) in benzene (10 mL) was treated with sodium isopropoxide (3.116 gm, 0.038 mole) to produce tin(IV) tetraisopropoxide and sodium chloride.e sodium chloride precipitate was removed by �ltration, and the solvent was removed by distillation.e solution of tin(IV) tetraisopropoxide (3.528 gm, 0.0095 mole) and ligand (2.372 gm, 0.01 mole) was re�uxed in benzene for 8-10 h.ese reactions proceed with the liberation of isopropanol, which is removed azeotropically with benzene.

Result and Discussion
All the newly synthesized complexes are colored solids and soluble in common organic solvents.e elemental analysis of these complexes is presented in Table 1.
3.1.Infrared Spectra.e characteristic infrared frequencies of the tin(IV) complexes are given in Table 2.It has been suggested, Schiff bases have a tautomeric structure (Figure 1), which means that pure Schiff bases exist in keto-amine and phenol-imine forms [12], but upon complex formation, they may exist only in the imine form.e complexes

S. no. a
Complex Azomethine proton Methylene proton Naphthylidene group proton 1 and 3 do not show a strong band in the region of 3500-3300 cm − due to (OH/NH) [13], indicating deprotonation of the phenolic and carboxylic oxygen of the Schiff bases on complex formation with the tin metal.In the complexes, two bands presumably due to asymmetric stretching frequencies  as (COO) and symmetric stretching frequencies  s (COO) are observed at 1640-1655 and 1389-1398 cm − , respectively.In the complexes, the differences [Δv(COO)] between  as (COO) and  s (COO) are >200 cm − , indicating the unidentate coordination of the carboxylate group to the tin metal [14].In the lower frequency region, the medium band observed at about 415-432 cm − in the spectra of the complexes has been assigned to the (N → Sn) vibration [15][16][17].

3.2.
1 H NMR Spectra.Table 3 shows the chemical shis ( in ppm) of various protons in metal complexes.e absence of a signal due to the -OH proton at  12.00-13.00ppm suggests deprotonation of the phenolic/enolic/carboxylic oxygen atoms of the ligand on complexation [15].e 1 H NMR Spectra of the complexes revealed a signal in the region  8.30-9.16ppm due to the azomethine (-N=CH-) proton [18].e multiplets between  6.89-7.93ppm are assigned to the naphthylidene group protons.

Conclusion
Based on stoichiometries and the physicochemical studies, penta-and octahedral coordination around tin(IV) has been proposed.e tentatively proposed structures of these complexes are shown in Figure 2.

List of Abbreviations
NaOPr