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Article

Linearly Polarized UV Light-Induced Optical Anisotropy of PVA Films and Flexible Macrocycle Schiff Base Ni(II), Cu(II), Zn(II) Dinuclear Complexes

1
Department of Chemistry, Faculty of Science, Tokyo University of Science, 1-3 Kagurazaka, Tokyo 162-8601, Japan
2
Department of Applied Sciences and Humanities, Faculty of Engineering and Technology, Jamia Millia Islamia, New Delhi 110025, India
*
Author to whom correspondence should be addressed.
Symmetry 2018, 10(12), 760; https://doi.org/10.3390/sym10120760
Submission received: 28 November 2018 / Revised: 12 December 2018 / Accepted: 12 December 2018 / Published: 17 December 2018
(This article belongs to the Special Issue Symmetry in Coordination Chemistry)

Abstract

:
Three dinuclear metal complexes (comprised of six-coordinated nNi2L and five-coordinated nCu2L and nZn2L) were confirmed by means of elemental analysis, UV-vis and IR spectra, and single X-ray crystal structural analysis in a spectroscopic study. The stable structures of these nNi2L, nCu2L, and nZn2L complexes in poly(vinylalcohol) (PVA) films were analyzed using UV-vis spectra. The molecular orientation of hybrid PVA film materials after linearly polarized light irradiation was analyzed to obtain the polarized spectra and dichroic ratio. Among the three materials, nNi2L and nZn2L complexes indicated an increasing optical anisotropy that depended on the flexibility of the complexes. We have included a discussion on the formation of the pseudo-crystallographic symmetry of the components in a soft matter (PVA films).

1. Introduction

Organic polymers or liquid crystals, including azo-groups, show optical anisotropy after linearly polarized UV light irradiation, which is the so-called Weigert effect (i.e., polarized light induces optical anisotropy of azo-compounds). It was reported in prior literature [1,2]. To detect such optical anisotropy, polarized absorption UV-vis (electronic) [3] or infrared (IR) [4] spectroscopy was employed previously. Several researchers have investigated hybrid materials for photochromic azo-compounds [5,6,7,8,9], as well as azo-compounds and metal complexes [10], or azo-groups containing metal complexes in various polymer films [11,12,13,14,15,16]. For such hybrid materials, the chirality of metal complexes or the azo-compounds plays a role in the detection of a separate component of composites [17,18]. In addition, the intermolecular interactions between the components and polymers should also be considered in the discussion on supramolecular chirality and photo-induced molecular arrangement [19]. This concept was developed to investigate matrix proteins using chiral molecular recognition between the protein and (chiral) metal complexes, which were expected to fit both molecular shapes through the rotation of guest molecules by light irradiation [20,21].
Besides the azo-compounds, some components that have a large dipole moment or polarity may be candidates that exhibit light-induced molecular arrangements like the azo-compounds. However, the power to control their alignment may be weaker than in azo-compounds, due to the Weigert effect. Previously, we have attempted to compare some dinuclear complexes with/without azo-compounds [22,23]. Such a strategy may be promising to employ various metal complexes more freely than the separated composites of the azo-compounds and metal complexes, when using electronic properties derived from the organic ligand moieties. However, such developments were limited to the molecular-level properties of structures, such as the shape or flexibility of ligands, the expected supramolecular interactions [24], chirality (symmetry), and the tests for “light-induced” supramolecular-level structural properties. For example, crystal symmetry similar to materials in the solid state, has not yet been considered.
In this study, we employed achiral dinuclear Schiff base nickel(II), copper(II), and zinc(II) complexes (hereinafter abbreviated as nNi2L, nCu2L, and nZn2L, respectively), incorporating the flexibility of macrocyclic ligands and the complexes’ hybrid poly(vinylalcohol) (PVA) films, a water-soluble polymer potentially forming hydrogen bonds, without azo-moieties. These hybrid materials were investigated for a molecular and material-level change after UV light irradiation. A previous study was carried out using chiral and rigid dinuclear Schiff base complexes, including azo-dyes in PVA film [23]. For comparison, we explored the achiral symmetry and molecular flexibility of the components’ assuming symmetry operations in the crystals at this time.

2. Materials and Methods

2.1. Preparations of the Complexes

All experiments were carried out in our chemistry laboratory. All the reagents and solvents were of the highest commercial grade available (Aldrich, Wako, or TCI), and were used as received without further purification. As shown in Scheme 1, 2,6-dimethylphenol and the complexes were synthesized according to the procedure described in References [23,25], for use in the spectroscopic study after confirming the composition as follows.
nNi2L: Yield: 31.1%. IR (KBr): 1643 cm−1 (s) (C=N). Anal. Found C; 42.52, H; 3.60, N; 7.64%. Calcd. C; 42.34, H; 5.33, N; 8.23% for C22H22Cl2N4Ni2O2(MeOH)2(H2O)3.
nCu2L: Yield: 11.8%. IR (KBr): 1639 cm−1 (s) (C=N). Anal. Found C; 41.54, H; 3.88, N; 8.81%. Calcd. C; 41.58, H; 4.60, N; 8.82% for C22H22Cl2Cu2N4O2(H2O)3.5.
nZn2L: Yield: 30.7% IR (KBr): 1638 cm−1 (s) (C=N). Anal. Found C; 40.39, H; 3.50, N; 7.96%. Calcd. C; 40.24, H; 3.38, N; 8.20% for C22H22Cl2N4O2Zn2(CHCl3)0.9. 1H-NMR (DMSO-d6, 300 MHz): δ 1.985 (m, 4H), 3.834 (m, 4H), 6.834 (t, 2H), 7.535 (d, 4H), 8.384 (d, 4H).

2.2. Preparation of the PVA Hybrid Cast Films

Aqueous solutions (0.5 mM) of each complex nNi2L, nCu2L, and nZn2L, were mixed with PVA (10 wt%) and cast onto a slide glass on a hot plate (333 K) for 4 days, to obtain hybrid film materials for the optical experiments.

2.3. Physical Measurements

Elemental analyses were carried out with a Perkin-Elmer 2400II CHNS/O analyzer (Perkin-Elmer, Waltham, MA, USA) at the Tokyo University of Science. Infrared (IR) spectra were recorded on a JASCO FT-IR 4200 spectrophotometer (JASCO, Tokyo, Japan) in the range between 4000 and 400 cm−1 at 298 K. (Polarized) electronic (UV-vis) spectra were measured on a JASCO V-650 spectrophotometer (JASCO, Tokyo, Japan) equipped with a polarizer in the range between 800 and 220 nm at 298 K. 1H-NMR spectra were recorded on a JEOL JMN-300 spectrometer (300 MHz) (JEOL, Tokyo, Japan). Fluorescence spectra were measured on a JASCO FP-6200 spectrophotometer (JASCO, Tokyo, Japan) in the range between 720 and 220 nm at 298 K. Photo-illumination was carried out using a lamp (1.0 mW/cm2) with optical filters (UV λ = 200–400 nm), producing a sample using the optical fibers and polarizer through the optical filters.

2.4. X-ray Crystallography

Prismatic single crystals were glued onto a glass fiber and coated with a thin layer of epoxy resin to measure the diffraction data. Intensity data were collected on a Bruker APEX2 CCD diffractometer with graphite monochromated Mo Kα radiation (λ = 0.7107 Å). Data analysis was carried out using the SAINT program package (2012). The structures were solved using direct methods with a SHELXS-97 and expanded by Fourier techniques. The structures were also refined using full-matrix least-squares methods, based on the F2 using the SHELXL-97 program [26]. An empirical absorption correction was applied using the SADABS program. All non-hydrogen atoms were readily located and refined using anisotropic thermal parameters. All hydrogen atoms were located at geometrically calculated positions and were refined using riding models.
Crystallographic data for nNi2L (CCDC 1569974, see Supplementary Materials): C24H28Cl2N4Ni2O4, orthorhombic, Pbca, Z = 4, a = 16.4576(10), b = 9.3159(6), c = 16.5338(10) Å, V = 2534.9(3) Å3, ρcalc = 1.637 g/cm3, μ = 1.735 mm−1, F(000) = 1288.0, S = 0.859, R1[I > 2σ(I)] = 0.0332, w R2 = 0.1090.
Crystallographic data for nCu2L (CCDC 1569973, see Supplementary Materials): C22H32Cl2Cu2N4O8, monoclinic, C2/m, Z = 2, a = 7.575(3), b = 15.369(7), c = 11.708(5) Å, β = 93.244(5)°, V = 1360.9(10) Å3, ρcalc = 1.656 g/cm3, μ = 1.812 mm−1, F(000) = 696.0, S = 1.223, R1[I > 2σ(I)] = 0.0592, w R2 = 0.1585.
Crystallographic data for nZn2L (CCDC 1569972, see Supplementary Materials): C22H22Cl2N4O2Zn2, monoclinic, Cc, Z = 4, a = 16.571(3), b = 28.098(3), c = 20.346(2) Å, β = 103.374(2)°, V = 9216(2) Å3, ρcalc = 1.661 g/cm3, μ = 2.347 mm−1, F(000) = 4672, S = 1.848, R1[I > 2σ(I)] = 0.0536, w R2 = 0.1015.

3. Results and Discussion

3.1. Structural Characterization

Figure 1, Figure 2 and Figure 3 exhibit the crystal structures of the nNi2L, nCu2L, and nZn2L, respectively, confirming the axial ligands and chirality around the asymmetric carbon atoms. No remarkable geometrical values were found in the covalent bonds of the ligands [25].

3.2. Spectral Characterization

The IR spectra of all the three complexes nNi2L, nCu2L, and nZn2L showed a strong band of 1643, 1639, and 1648 cm−1, respectively, which was assignable to the υ (C=N) stretching frequency of the iminic bond present in the complex moiety [27].
UV-Visible (electronic) spectra of all the complexes in solid state, aqueous solution, and PVA were estimated and are shown in Figure 4. It was clear from these spectra that all the metal complexes showed similar structures, as the UV-vis spectra in the PVA were similar to those in the aqueous solution.
For the nZn2L, we measured the corresponding UV-vis spectra after UV light (360 and 420 nm) irradiation for 5 min (Figure 5, right), as well as the luminescence spectra excited by UV light in an aqueous solution (Figure 5, left). Absorbance of the UV-vis spectra for the nZn2L aqueous solution decreased by UV light, suggesting that the electronic state of the nZn2L had changed into the excited state.

3.3. Polarized Light Induced-Anisotropic Molecular Orientation

Prior to the photochemical experiments of the hybrid film materials, we investigated the free volume to rotate molecules in a PVA matrix, the stability against UV light, and the Weigert effect, like the molecular alignment of the complexes in a PVA matrix induced by linearly polarized UV-light (during or after heating to dry to form films), as described in References [27,28]. For example, we attempted to irradiate linearly polarized UV light on nZn2L + PVA for 10 min, and we measured fine changes in the polarized photoluminescence (PL) spectra equipped with an angular polarizer from 0 to 90 degrees [29]. We also obtained linear dichroism by means of polarized UV-vis spectra before and after linearly polarized UV light. Intensity at 0 degrees was larger than that at 90 degrees, suggesting that nZn2L changed its molecular orientation similar to the Weigert effect, and it kept a stable chemical species.
Linearly polarized UV-light-induced optical anisotropy in PVA hybrid cast films was successfully observed for the nNi2L + PVA and nZn2L + PVA, although nCu2L + PVA did not exhibit clear dichroism. The polarized electronic spectrum of the hybrid materials: nNi2L + PVA, nCu2L + PVA, and nZn2L + PVA, for every 5 degrees after irradiation with polarized UV light (200–400 nm), was recorded as shown in Figure 6, Figure 7 and Figure 8, respectively, and summarized in Table 1, with the R and S values for the degree of optical anisotropy. The degree of photoinduced optical anisotropy of spectra is described by the S and R parameters, as in Reference [30]:
S = (AparallelAperpendicular)/(2Aperpendicular + Aparallel)
R = Aparallel/Aperpendicular
where Aperpendicular and Aparallel values denote the absorbance measured by the measuring polarizers that are perpendicular or parallel to the electric vector of irradiation polarized light. Thus, S = 0 and R = 1, and both the S and R parameters change with increasing anisotropic molecular orientation due to dichroism.
The nNi2L + PVA and nZn2L + PVA hybrid materials exhibited optical anisotropy in the charge transfer (CT) band (associated with the coordination environment), as well as in the π−π* band (associated with the organic ligand) after irradiation with the linearly polarized light. This suggested that the transition electric dipole moment was orientated parallel to the linearly polarized light (Figure 6, Figure 7 and Figure 8). Typically, the R value 0.967 → 0.913 of the CT band of nNi2L + PVA increased with the anisotropic alignment in the films. This indicated the rigid nNi2L and nZn2L orientation of the dipole moment induced by linearly polarized light. However, the flexible nCu2L did not exhibit optical anisotropy, suggesting that the orientation of the metal complex did not depend on the flexibility (hardness) of the structure around the metal in a complex [25].

3.4. Making Pseudo-Crystallographic Symmetry

However, like the crystalline state, we also successfully induced anisotropic molecular orientation in the PVA films’ using linearly polarized UV light irradiation. Recently, the alignment controls of molecules and nanoparticles have been studied to give photo properties [31]. X-ray diffraction spots were obtained, if possible, and the molecular structure was determined in the case of limited conditions [32].
To form symmetry elements like crystals with polarized light in the polymer films (Scheme 1), the intermolecular interactions in chiral crystals of achiral molecules forming screw axes were used as a reference. To form a two-fold screw axis in the crystals, we considered the Weigert effect associated with azobenzene and linearly polarized light originally (and applied circularly polarized light for helical alignments) [33]. For example, it is necessary in finding a new chiral crystallization of compounds containing azobenzene moiety, or at least in finding a new chiral crystallization of achiral compounds without azobenzene moiety. New examples of chiral crystallization (P21) were proposed to observe: (1) An azo-organic compound with a long π-conjugated system, and (2) a five-membered ring with aromaticity. In both crystals, the component molecules were helically connected along one axis by hydrogen bonds.
Moreover, extracting intermolecular interactions from the crystal structure analysis of (a)chiral crystals may be important for induction of the anisotropic or helical orientation of molecules (essentially the dipole moments [34]) in polymer films, using polarized UV light irradiation [35,36]. However, due to the possibility of topological control and a lesser requirement for the molecular symmetry of the components (Scheme 2), (polarized UV) light may represent promising external stimuli for the current purpose.

4. Conclusions

After linearly polarized UV light irradiation, the optical anisotropy of nNi2L and nZn2L parallel to the linearly polarized light in PVA was obtained. We attempted to irradiate linearly polarized monochromatic UV light (360 nm) on nNi2L + PVA, indicating optical anisotropy and molecular orientation. However, this angular optical anisotropy (R value 0.967 → 0.913) was vertical to the CT band of the nNi2L + PVA after linearly polarized continuous light irradiation (R value 0.998 → 1.013). As a result, we successfully observed linearly polarized UV light-induced molecular orientation, particularly for two materials (nNi2L + PVA and nZn2L + PVA).

Supplementary Materials

The following are available online at https://www.mdpi.com/2073-8994/10/12/760/s1. CCDC 1569974, 1569973, and 1569972 contain the supplementary crystallographic data for nNi2L, nCu2L, and nZn2L, respectively. These data can be obtained free of charge via www.ccdc.cam.ac.uk, or from the Cambridge Crystallographic Data Centre, 12 Union Road, CB2 1EZ Cambridge, England, UK; Fax: (+44) 01223 336033; or E-Mail: [email protected].

Author Contributions

M.T. and S.Y. performed the experiments; T.H., S.N., and T.A. wrote the paper.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. (i) Crystal structures of nNi2L showing the atom labeling schemes. Hydrogen atoms and crystalline water were omitted for clarity. (ii) Crystal packing viewed from the crystallographic a axis. Ni(1) − Cl(1) = 2.4267(8) Å, Ni(1) − O(1) = 2.042(2) Å.
Figure 1. (i) Crystal structures of nNi2L showing the atom labeling schemes. Hydrogen atoms and crystalline water were omitted for clarity. (ii) Crystal packing viewed from the crystallographic a axis. Ni(1) − Cl(1) = 2.4267(8) Å, Ni(1) − O(1) = 2.042(2) Å.
Symmetry 10 00760 g001aSymmetry 10 00760 g001b
Figure 2. (i) Crystal structures of nCu2L showing the atom labeling schemes. Hydrogen atoms were omitted for clarity. (ii) Crystal packing viewed from the crystallographic a axis. Cu(1) − Cl(1) = 2.588(13) Å.
Figure 2. (i) Crystal structures of nCu2L showing the atom labeling schemes. Hydrogen atoms were omitted for clarity. (ii) Crystal packing viewed from the crystallographic a axis. Cu(1) − Cl(1) = 2.588(13) Å.
Symmetry 10 00760 g002
Figure 3. (i) Crystal structures of nZn2L showing the atom labeling schemes. Hydrogen atoms and crystalline water were omitted for clarity. (ii) Crystal packing viewed from the crystallographic a axis. Zn(7) − Cl(11) = 2.296(2) Å, Zn(2) − Cl(12) = 2.297(3) Å.
Figure 3. (i) Crystal structures of nZn2L showing the atom labeling schemes. Hydrogen atoms and crystalline water were omitted for clarity. (ii) Crystal packing viewed from the crystallographic a axis. Zn(7) − Cl(11) = 2.296(2) Å, Zn(2) − Cl(12) = 2.297(3) Å.
Symmetry 10 00760 g003
Figure 4. UV-vis spectra of the nNi2L, nCu2L, and nZn2L (left, center, right) in the solid state, aqueous solution, and PVA (top, middle, bottom).
Figure 4. UV-vis spectra of the nNi2L, nCu2L, and nZn2L (left, center, right) in the solid state, aqueous solution, and PVA (top, middle, bottom).
Symmetry 10 00760 g004
Figure 5. UV-vis spectra and 3D luminescence spectra for nZn2L in aqueous solutions under UV light irradiation.
Figure 5. UV-vis spectra and 3D luminescence spectra for nZn2L in aqueous solutions under UV light irradiation.
Symmetry 10 00760 g005
Figure 6. Polarized electronic spectra for nNi2L + PVA after linearly polarized UV light irradiation (min). Polarizer angle depends on the absorbance of electronic spectra in the π − π* (left) and CT (right) bands for nNi2L + PVA after linearly polarized UV light irradiation.
Figure 6. Polarized electronic spectra for nNi2L + PVA after linearly polarized UV light irradiation (min). Polarizer angle depends on the absorbance of electronic spectra in the π − π* (left) and CT (right) bands for nNi2L + PVA after linearly polarized UV light irradiation.
Symmetry 10 00760 g006
Figure 7. Polarized electronic spectra for nCu2L + PVA after linearly polarized UV light irradiation (min). Polarizer angle depends on the absorbance of electronic spectra in the π − π* (left) and CT (right) bands for nCu2L + PVA after linearly polarized UV light irradiation.
Figure 7. Polarized electronic spectra for nCu2L + PVA after linearly polarized UV light irradiation (min). Polarizer angle depends on the absorbance of electronic spectra in the π − π* (left) and CT (right) bands for nCu2L + PVA after linearly polarized UV light irradiation.
Symmetry 10 00760 g007
Figure 8. Polarized electronic spectra for nZn2L + PVA after linearly polarized UV light irradiation (min). Polarizer angle depends on the absorbance of electronic spectra in the π − π* (left) and CT (right) bands for nZn2L + PVA after linearly polarized UV light irradiation.
Figure 8. Polarized electronic spectra for nZn2L + PVA after linearly polarized UV light irradiation (min). Polarizer angle depends on the absorbance of electronic spectra in the π − π* (left) and CT (right) bands for nZn2L + PVA after linearly polarized UV light irradiation.
Symmetry 10 00760 g008
Scheme 1. Concept to induce pseudo-crystallographic symmetry in polymer films using polarized light.
Scheme 1. Concept to induce pseudo-crystallographic symmetry in polymer films using polarized light.
Symmetry 10 00760 sch001
Scheme 2. Molecular symmetry imposed in crystal symmetry. Example for nNi2L in Pbca (#61).
Scheme 2. Molecular symmetry imposed in crystal symmetry. Example for nNi2L in Pbca (#61).
Symmetry 10 00760 sch002
Table 1. The R and S values at the π − π*and CT bands for the composite with PVA after linearly polarized UV light irradiation.
Table 1. The R and S values at the π − π*and CT bands for the composite with PVA after linearly polarized UV light irradiation.
t/minR (π − π*)S (π − π*)R (CT)S (CT)
nNi2L + PVA00.9940−0.00200.998−0.0015
50.9929−0.00241.0050.0016
100.9951−0.00161.0130.0042
nCu2L + PVA00.9845−0.005180.9855−0.0049
50.9870−0.004350.9990−0.00032
100.9876−0.004141.0010.00032
nZn2L + PVA01.0070.00231.0100.0033
0.51.0030.00111.1080.0346
10.9247−0.02581.0180.0061
30.9135−0.02971.0080.0026
50.9209−0.02710.9935−0.0022
100.9826−0.00581.0600.0196

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Takase, M.; Yagi, S.; Haraguchi, T.; Noor, S.; Akitsu, T. Linearly Polarized UV Light-Induced Optical Anisotropy of PVA Films and Flexible Macrocycle Schiff Base Ni(II), Cu(II), Zn(II) Dinuclear Complexes. Symmetry 2018, 10, 760. https://doi.org/10.3390/sym10120760

AMA Style

Takase M, Yagi S, Haraguchi T, Noor S, Akitsu T. Linearly Polarized UV Light-Induced Optical Anisotropy of PVA Films and Flexible Macrocycle Schiff Base Ni(II), Cu(II), Zn(II) Dinuclear Complexes. Symmetry. 2018; 10(12):760. https://doi.org/10.3390/sym10120760

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Takase, Masahiro, Shiomi Yagi, Tomoyuki Haraguchi, Shabana Noor, and Takashiro Akitsu. 2018. "Linearly Polarized UV Light-Induced Optical Anisotropy of PVA Films and Flexible Macrocycle Schiff Base Ni(II), Cu(II), Zn(II) Dinuclear Complexes" Symmetry 10, no. 12: 760. https://doi.org/10.3390/sym10120760

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