Mesogenic Polyelectrolyte Gels Absorb Organic Solvents and Liquid Crystalline Molecules

In this paper, mesogenic polyelectrolyte gels (MPEgels) tethering mesogenic groups on the side chains were synthesized from a mesogenic monomer and ionic monomer via a conventional radical polymerization process. The obtained MPEgels absorbed various organic solvents in a wide range of dielectric constants from chloroform (ε = 7.6) to DMSO (ε = 46.5). The electrostatic repulsion among the polymer chains and the osmotic pressure between the interior and exterior of the MPEgel is responsible for the high swelling ability, revealed by the common ion effect using tetra(n-hexyl)ammonium tetra(3,5-bis(trifluoromethyl)phenylborate (THATFPB). The obtained MPEgels could also absorb liquid crystalline molecules such as 4-cyano-4’-pentylbiphenyl (5CB), analogously caused by the above-mentioned polyelectrolyte characteristic. The MPEgels exhibited liquid crystal transition temperature (TNI) on differential scanning calorimetry (DSC) measurement, and the increase of the ionic group content lowered TNI. The MPEgels absorbing liquid crystalline molecules exhibited differing TNI, dependent on the compatibility of the mesogenic group on the side chain to the liquid crystalline molecule.

As an unexplored solvent for polyelectrolyte gels, in this research, we focused on liquid crystalline molecules.Liquid crystalline molecules are substances in a state that has both properties of liquid fluidity and crystal anisotropy [39,40].Their attractive properties have been extensively investigated due to their potential application for displays [41][42][43][44], lasers [45][46][47], semiconductors [48], and so on, derived from their stimuli-responsive orientational ability.In addition, liquid crystal is known as an effective solvent, such as for polymerization [49,50], swelling gels [51][52][53][54], and forming nanofibers [55,56], and it offers a special orientation to the produced materials.Despite the characteristic of liquid crystalline molecules as a solvent, no studies have paid attention to the use of polyelectrolyte gels in a liquid crystalline molecule because of the slight compatibility between conventional polyelectrolytes and liquid crystal molecules.In order to address this circumstance, we designed polyelectrolyte gels efficiently functioning in a liquid crystalline molecule by utilizing the lipophilic ion pair described above.In this paper, we prepared mesogenic polyelectrolyte gels tethering mesogenic groups and ionic groups via a conventional radical polymerization process, and investigated their swelling and orientating properties.

Synthesis of Monomer M5
To a solution of compound 1 in dry CH 2 Cl 2 (200 mL) was added triethylamine (3.95 g, 3.9 mmol) under N 2 atmosphere.Then acryloyl chloride (3.76 g, 41.5 mmol) was added dropwise, and stirred for 14 h at room temperature.The mixture was washed with NaHCO 3 aq.and distilled water, and dried with MgSO 4 .
The solvent was removed under vacuum, and the residue was purified by silica gel chromatography (CH 2 Cl 2 ) to obtain monomer M5 as a white solid (2.98 g, 61%). 1

Synthesis of Monomer M6
The procedure was similar with that for compound M5. 1

Preparation of MPEG5-p and MPEG6-p
In a test tube, ionic monomer 3 and mesogenic monomer (M5 or M6) were dissolved in DMF (1 M, 120 µL).Then DMF solution of 1,6-hexanediol diacrylate (HDA, 0.1 M, 60 µL) and benzoyl peroxide (0.1 M, 60 µL) were added, and the mixture was completely degassed by the freeze-thaw method and sealed.The tube was heated at 80 ˝C for 24 h.After cooling to room temperature, the isolated gel was thoroughly washed by repeatedly immersing THF, and dried under vacuum.

Results and Discussion
The MPEgel tethering mesogenic group on the side chain (MPEGn-p) was prepared via conventional free radical polymerization of the mesogenic monomer (Mn, Scheme 1) and ionic monomer (3) initiated by benzoyl peroxide (BPO), using 1,6-hexanediol diacrylate (HDA) as the crosslinker (Scheme 2).The ionic monomer content is given by p, whereas n expresses the length of the alkyl linker on the mesogenic monomer.As a result of the 1 H NMR measurement of a linear polymer (MPEP5-5), the ionic monomer content was found to be 4.4%, showing good correlation with the 5% of feed ratio.The swelling degree of obtained MPEgels was investigated in organic solvents with various polarities from hexane (ε = 1.9) to DMSO (ε = 46.5),as shown in Figure 1 and Tables S1 and S2 in the Supplementary Materials.In non-polar solvents such as hexane and chloroform, the MPEgels showed a modest swelling degree, indicating no effect of introduced ionic groups.For example, the swelling degrees of MPEG6-5%, MPEG6-1%, and MPEG6-0% were 0.2, 1.0, and 0.4 in hexane, and 3.7, 5.3, and 6.5 in chloroform (Figure 1a).In these solvents, the extremely low polarity suppressed ionic dissociation of tetraalkylammonium tetrakis(3,5-bis(trifluoromethyl)phenyl) borate (TFPB), forming a tightly bound ion pair or highly aggregated species.Additionally, in alcoholic solvents such as hexanol, butanol, and methanol, the MPEgels were collapsed, due to the low compatibility of the polymer chain to the solvents.On the other hand, in THF, dichloromethane, cyclopentanone, 2-butanone, acetone, DMF, and DMSO, the MPEgels exhibited an obvious increment in swelling degrees driven by the introduction of the ionic group.The swelling degrees of MPEG6-5% and MPEG5-5% were 51 and 21 in THF, 98 and 59 in dichloromethane, 134 and 110 in cyclopentanone, 132 and 105 in 2-butanone, 114 and 91 in acetone, 288 and 193 in DMF, and 239 and 183 in DMSO.This behavior is attributed to the dissociation of the ion pair to free ions, causing electrostatic repulsion and osmotic pressure for the expansion of the polymer network and absorption of the solvents.These results indicated that the obtained MPEgels can act as a polyelectrolyte gel in various organic solvents by introducing TFPB salts.
the alkyl linker on the mesogenic monomer.As a result of the 1 H NMR measurement of a linear polymer (MPEP5-5), the ionic monomer content was found to be 4.4%, showing good correlation with the 5% of feed ratio.The swelling degree of obtained MPEgels was investigated in organic solvents with various polarities from hexane (ε = 1.9) to DMSO (ε = 46.5),as shown in Figure 1 and Tables S1 and S2 in the Supplementary Materials.In non-polar solvents such as hexane and chloroform, the MPEgels showed a modest swelling degree, indicating no effect of introduced ionic groups.For example, the swelling degrees of MPEG6-5%, MPEG6-1%, and MPEG6-0% were 0.2, 1.0, and 0.4 in hexane, and 3.7, 5.3, and 6.5 in chloroform (Figure 1a).In these solvents, the extremely low polarity suppressed ionic dissociation of tetraalkylammonium tetrakis(3,5-bis(trifluoromethyl)phenyl) borate (TFPB), forming a tightly bound ion pair or highly aggregated species.Additionally, in alcoholic solvents such as hexanol, butanol, and methanol, the MPEgels were collapsed, due to the low compatibility of the polymer chain to the solvents.On the other hand, in THF, dichloromethane, cyclopentanone, 2-butanone, acetone, DMF, and DMSO, the MPEgels exhibited an obvious increment in swelling degrees driven by the introduction of the ionic group.The swelling degrees of MPEG6-5% and MPEG5-5% were 51 and 21 in THF, 98 and 59 in dichloromethane, 134 and 110 in cyclopentanone, 132 and 105 in 2-butanone, 114 and 91 in acetone, 288 and 193 in DMF, and 239 and 183 in DMSO.This behavior is attributed to the dissociation of the ion pair to free ions, causing electrostatic repulsion and osmotic pressure for the expansion of the polymer network and absorption of the solvents.These results indicated that the obtained MPEgels can act as a polyelectrolyte gel in various organic solvents by introducing TFPB salts.In order to confirm the function of the polyelectrolyte, we investigated the common ion effect in the swelling behavior by the addition of tetra(n-hexyl)ammonium tetra(3,5-bis (trifluoromethyl)phenylborate (THATFPB) as a low molecular weight electrolyte.In THF, in which MPEgels showed an apparent increment of swelling degree with the introduction of the ionic group, the addition of 1 mM THATFPB resulted in decrease of the swelling degree, for example 12 to five in MPEG6-5%, six to four in MPEG6-1%, four to two in MPEG5-5%, and four to three in MPEG5-1% (Figure S1).On another front, a smaller effect was observed in DMF, presumably because of the high dissociation degree, even with the existence of the common ion.In chloroform, almost no change was detected due to the slight dissociation degree, due to almost no dissociation even without the common ion.These observations proved that the obtained MPEgels absorbed organic solvents by adopting the same mechanism as that of hydrogels in water.In order to confirm the function of the polyelectrolyte, we investigated the common ion effect in the swelling behavior by the addition of tetra(n-hexyl)ammonium tetra(3,5bis(trifluoromethyl)phenylborate (THATFPB) as a low molecular weight electrolyte.In THF, in which MPEgels showed an apparent increment of swelling degree with the introduction of the ionic group, the addition of 1 mM THATFPB resulted in decrease of the swelling degree, for example 12 to five in MPEG6-5%, six to four in MPEG6-1%, four to two in MPEG5-5%, and four to three in MPEG5-1% (Figure S1).On another front, a smaller effect was observed in DMF, presumably because of the high dissociation degree, even with the existence of the common ion.In chloroform, almost no change was detected due to the slight dissociation degree, due to almost no dissociation even without the common ion.These observations proved that the obtained MPEgels absorbed organic solvents by adopting the same mechanism as that of hydrogels in water.
We attested the swelling behavior of the MPEgels in a liquid crystalline molecule by employing 4-cyano-4'-pentylbyphenyl (5CB) as a solvent.The 5CB has an anisotropic molecular geometry, and offers different permittivity dependent on the molecular axis, parallel to the longer axis (ε = 17.9) and perpendicular to the longer axis (ε⊥ = 6.9).Compared to nonionic mesogenic gels (MPEG6-0%; Q = 4.1, MPEG5-0%; Q = 3.0), MPEgels with high ionic content (MPEG6-5%, MPEG5-5%) showed higher swelling degrees of 15 and 11, respectively (Figure 2).The MPEgel MPEG5-1% showed a moderate increase of swelling degree (Q = 6.3), whereas it was not observed in MPEG6-1% (Q = 4.3), probably due to the higher assembling effect derived from the longer alkyl chain of the mesogenic group with n = 6.Furthermore, the addition of THATFPB (1 mM) resulted in the collapse of MPEgels, especially with a higher ionic group content.This fact implies the prepared MPEgels can act as a polyelectrolyte gel even in the liquid crystalline molecule.We attested the swelling behavior of the MPEgels in a liquid crystalline molecule by employing 4-cyano-4'-pentylbyphenyl (5CB) as a solvent.The 5CB has an anisotropic molecular geometry, and offers different permittivity dependent on the molecular axis, parallel to the longer axis (ε = 17.9) and perpendicular to the longer axis (εK = 6.9).Compared to nonionic mesogenic gels (MPEG6-0%; Q = 4.1, MPEG5-0%; Q = 3.0), MPEgels with high ionic content (MPEG6-5%, MPEG5-5%) showed higher swelling degrees of 15 and 11, respectively (Figure 2).The MPEgel MPEG5-1% showed a moderate increase of swelling degree (Q = 6.3), whereas it was not observed in MPEG6-1% (Q = 4.3), probably due to the higher assembling effect derived from the longer alkyl chain of the mesogenic group with n = 6.Furthermore, the addition of THATFPB (1 mM) resulted in the collapse of MPEgels, especially with a higher ionic group content.This fact implies the prepared MPEgels can act as a polyelectrolyte gel even in the liquid crystalline molecule.
mesogenic" THATFPB.The TNI of 5CB originally appears at 34 °C, and the addition of THATFPB gradually decreased the TNI (23 °C with 50 mM THATFPB).Therefore, the introduction of ionic groups was responsible for the TNI decrease; however, the liquid crystallinity could be still preserved by proper selection of the structure of the mesogenic or ionic group content.The liquid crystallinity of the MPEgels was also confirmed by polarizing microscopy as shown in Figure S3.These MPEgels swollen in 5CB showed different behavior in the DSC measurement (Figure S4).The MPEG5-p exhibited only one exothermic peak, irrelevant to the original TNI of 5CB.On the other hand, MPEG6-p exhibited two separated peaks, with low or no ionic group content.These two peaks are assignable to the liquid crystal transition derived from 5CB (lower TNI) and the MPEgels (higher TNI).With the higher ionic group content (MPEG6-5%), the two peaks are coalesced, due to the decrease of the TNI of the MPEgel.This result also refers to the odd-even effect of the side chain, and thus MPEG5-p possesses higher interacting ability with 5CB because of the same length of the alkyl linker.

Conclusions
To summarize our results, we successfully prepared mesogenic polyelectrolyte gels tethering mesogenic groups and lipophilic ion groups on the side chains.The obtained MPEgels absorbed various organic solvents in a wide range of dielectric constants from chloroform (ε = 7.6) to DMSO (ε = 46.5),except for extremely nonpolar solvents (ε < 4.8) or alcohols.Their high swelling ability resulted from electrostatic repulsion among the polymer chains and osmotic pressure between the interior and exterior of the MPEgel, revealed by common ion effect using THATFPB.Additionally, the MPEgels could absorb liquid crystalline molecules such as 5CB, also driven by the abovementioned polyelectrolyte feature.The MPEgels showed liquid crystal transition temperature (TNI) on the DSC measurement, and an increase of the ionic group content resulted in a decrease of TNI, due to lowering the liquid crystallinity by the ion-dipole interaction.The MPEgels absorbing liquid crystalline molecules exhibited differing TNI dependent on the compatibility of the mesogenic group on the side chain to the liquid crystalline molecule.These findings will allow us to explore liquid With respect to the liquid crystallinity, differential scanning calorimetry (DSC) was conducted on the obtained MPEgels in a shrunken state (Figure 3).The nonionic mesogenic gels (MPEG6-0% and MPEG5-0%) exhibited the transition temperature (T NI ) at 125 and 106 ˝C, respectively.The introduction of ionic groups resulted in a decrease of T NI , for example 117 ˝C for MPEG6-1% and 94 ˝C for MPEG5-1%.Larger amounts of ionic groups gave rise to a further decrease of T NI (94 ˝C for MPEG6-5%) or the disappearance of T NI for MPEG5-5%.The difference between MPEG6-5% and MPEG5-5% derived from the higher liquid crystallinity of MPEG6-5%, attributed to the odd-even effect of mesogenic molecules [57].Indeed, 4-cyano-4'-hexyloxybiphenyl (6OCB) shows a higher T NI at 76 ˝C compared to that of 4-cyano-4'-pentyloxybiphenyl (5OCB, T NI = 68 ˝C).The fact that the introduction of ionic groups led to the decrease of T NI was also confirmed by the DSC measurement of 5CB with a certain amount of THATFPB (Figure S2), because of the suppression effect of "non-mesogenic" THATFPB.The T NI of 5CB originally appears at 34 ˝C, and the addition of THATFPB gradually decreased the T NI (23 ˝C with 50 mM THATFPB).Therefore, the introduction of ionic groups was responsible for the T NI decrease; however, the liquid crystallinity could be still preserved by proper selection of the structure of the mesogenic or ionic group content.The liquid crystallinity of the MPEgels was also confirmed by polarizing microscopy as shown in Figure S3.
Polymers 2016, 8, 148 6 of 9 mesogenic" THATFPB.The TNI of 5CB originally appears at 34 °C, and the addition of THATFPB gradually decreased the TNI (23 °C with 50 mM THATFPB).Therefore, the introduction of ionic groups was responsible for the TNI decrease; however, the liquid crystallinity could be still preserved by proper selection of the structure of the mesogenic or ionic group content.The liquid crystallinity of the MPEgels was also confirmed by polarizing microscopy as shown in Figure S3.These MPEgels swollen in 5CB showed different behavior in the DSC measurement (Figure S4).The MPEG5-p exhibited only one exothermic peak, irrelevant to the original TNI of 5CB.On the other hand, MPEG6-p exhibited two separated peaks, with low or no ionic group content.These two peaks are assignable to the liquid crystal transition derived from 5CB (lower TNI) and the MPEgels (higher TNI).With the higher ionic group content (MPEG6-5%), the two peaks are coalesced, due to the decrease of the TNI of the MPEgel.This result also refers to the odd-even effect of the side chain, and thus MPEG5-p possesses higher interacting ability with 5CB because of the same length of the alkyl linker.

Conclusions
To summarize our results, we successfully prepared mesogenic polyelectrolyte gels tethering mesogenic groups and lipophilic ion groups on the side chains.The obtained MPEgels absorbed various organic solvents in a wide range of dielectric constants from chloroform (ε = 7.6) to DMSO (ε = 46.5),except for extremely nonpolar solvents (ε < 4.8) or alcohols.Their high swelling ability These MPEgels swollen in 5CB showed different behavior in the DSC measurement (Figure S4).The MPEG5-p exhibited only one exothermic peak, irrelevant to the original T NI of 5CB.On the other hand, MPEG6-p exhibited two separated peaks, with low or no ionic group content.These two peaks are assignable to the liquid crystal transition derived from 5CB (lower T NI ) and the MPEgels (higher T NI ).With the higher ionic group content (MPEG6-5%), the two peaks are coalesced, due to the decrease of the T NI of the MPEgel.This result also refers to the odd-even effect of the side chain, and thus MPEG5-p possesses higher interacting ability with 5CB because of the same length of the alkyl linker.

Conclusions
To summarize our results, we successfully prepared mesogenic polyelectrolyte gels tethering mesogenic groups and lipophilic ion groups on the side chains.The obtained MPEgels absorbed various organic solvents in a wide range of dielectric constants from chloroform (ε = 7.6) to DMSO (ε = 46.5),except for extremely nonpolar solvents (ε < 4.8) or alcohols.Their high swelling ability resulted from electrostatic repulsion among the polymer chains and osmotic pressure between the interior and exterior of the MPEgel, revealed by common ion effect using THATFPB.Additionally, the MPEgels could absorb liquid crystalline molecules such as 5CB, also driven by the above-mentioned polyelectrolyte feature.The MPEgels showed liquid crystal transition temperature (T NI ) on the DSC measurement, and an increase of the ionic group content resulted in a decrease of T NI , due to lowering the liquid crystallinity by the ion-dipole interaction.The MPEgels absorbing liquid crystalline molecules exhibited differing T NI dependent on the compatibility of the mesogenic group on the side chain to the liquid crystalline molecule.These findings will allow us to explore liquid crystalline molecules as a medium for polyelectrolytes toward applications including soft actuators, artificial muscles, or nonlinear optical devices.

Figure 2 .
Figure 2. Swelling degree of (a) MPEG6-p and (b) MPEG5-p in a liquid crystalline molecule 5CB with and without THATFPB.

Figure 2 .
Figure 2. Swelling degree of MPEG6-p and (b) MPEG5-p in a liquid crystalline molecule 5CB with and without THATFPB.

Figure 2 .
Figure 2. Swelling degree of (a) MPEG6-p and (b) MPEG5-p in a liquid crystalline molecule 5CB with and without THATFPB.