Maltose-pendant polymer/mica nanocomposites were prepared by a solution intercalation method. For organic composite part, 1) maltose-pendant polymer (homopolymer) and 2) the copolymer of maltose-pendant monomer and a small amount of N,N-Dimethylamino propylacrylamide, methyl chloride quartenary were used. The morphological studies (XRD and FE-SEM) revealed that the hybrid of maltose-pendant polymer was a conventional phase separated composite. On the other hand, the hybrid using the copolymer exhibited exfoliated structure. Both the conventional composite of maltose-pendant polymer and the nanocomposite of copolymer were applied to a coating material for oxygen gas barrier layer on a nylon-6 film, and oxygen transmission rates of the films were evaluated. Maltose-pendant polymer had a good oxygen barrier property under dry condition, and the barrier property under wet condition was improved by the hybridization with mica. In contrast, the barrier property of copolymer was slightly inferior to that of maltosependant polymer. However, under dry condition, it can be seen that the nanocomposite of copolymer improves the barrier property more effectively than the case of conventional composite of maltose-pendant polymer.
Oxygen gas barrier films have been widely used for food and pharmaceutical packaging in order to protect their contents from oxidation and denaturation. However, since these films have been produced in large quantities and have been disposed by incineration, development of materials must be attempted with considering the reduction of environmental load after use as well as the improvement of their barrier properties. Biodegradable polymer-based materials are, therefore, suitable for these packaging applications [
Cellulose (Cellophane), one of the most abundant natural resources, exhibits an oxygen gas barrier property under a dry condition. But the poor processability and the low solubility in common solvents originated from the tight inter- and intra-molecular hydrogen bonding have prevented the commercial applications of this material. Previously, in order to improve these drawbacks, our group synthesized water-soluble oligosaccharide-pendant polymers [
In the present paper, we synthesized maltose-pendant polymer (
Polymer/clay nanocomposites, where nanometer-thin clay platelets are dispersed in polymer matrices, possess enhanced gas barrier properties, and hence they have been investigated in many laboratories [
In the present study, we used mica as inorganic filler, considering its high aspect ratio, over 1000. However, the charge density of mica platelets is high (about 1 equiv/mol), and platelets are tightly held together by elec- trostatic forces. Therefore, for the purpose of exfoliating mica platelets individually, we utilized the maltose- pendant polymer containing cationic groups as well (
Maltose monohydrate and ammonium hydrogencarbonate were obtained from Wako Pure Chemical Industries, Ltd. (Osaka, Japan). 2-isocyanatoethyl methacrylate (2-IEM) was obtained from Showa Denko K. K. (Tokyo, Japan). N,N-Dimethylamino propylacrylamide, methyl chloride quartenary (DMAPAA-Q) was obtained from KOHJIN Film & Chemicals Co., Ltd. (Tokyo, Japan). Ammonium peroxodisulfate (APS) and N,N,N’,N’-Te- traethylethylenediamine (TEEDAm) were obtained from Wako Pure Chemical Industries, Ltd. (Osaka, Japan) and KANTO CHEMICAL CO., INC. (Tokyo, Japan), respectively. Synthetic mica dispersion (NTS-10) was obtained from TOPY INDUSTRIES, LIMITED (Tokyo, Japan). All were used without purification.
Chemical structures of a series of maltose-pendant polymers: (a) maltose-pendant polymer; (b) the copolymer of maltose-pendant monomer and DMAPAA-Q
Previously, our group prepared and characterized oligosaccharide-pendant polymers [
Maltose monohydrate (10.53 g, 29.22 mmol) was dissolved in water (150 cm3), and ammonium hydrogen- carbonate (28.5 g) was added at intervals of 24 h, and was stirred at 37˚C for 4 days. The solution was diluted with water (200 cm3) and concentrated to 50 cm3. This procedure was repeated until the ammonia odor had dis- appeared. HPLC showed that the purity of freeze-dried product was 64.6%.
The obtained maltosylamine (5.00 g, 9.50 mmol) was dissolved in a 1.0 × 10−3 M KOH aqueous solution (100 cm3). 2-IEM (3.67 g, 23.7 mmol) was added to the solution and stirred at 3˚C for 12 h with producing white pre- cipitate as a by-product. This precipitate was removed by filtration. The filtrate was washed with diethyl ether in order to remove unreacted 2-IEM, and then freeze-dried. The crude product was dissolved in water/methanol and recrystallized from acetone/diethyl ether. The yield was 5.44 g (purity 76.4%).
The synthesized maltose-pendant monomer (3.80 g, 5.85 mmol) was dissolved in water (20 cm3). Air was degassed from the solution by nitrogen gas, and APS (13.3 mg, 0.0585 mmol) and TEEDAm (100.8 mg, 0.585 mmol) were added to the solution. The mixture was stirred at 0˚C under nitrogen gas atmosphere for 3 h. The obtained crude polymer was purified by dialyzing in a dialysis tube (Spectra/por 3, Spectrum Laboratories, Inc.) for 3 days in order to remove unreacted monomer. The product was finally freeze-dried, giving a white powdery polymer. The yield was 2.21 g.
The maltose-pendant polymer containing cationic groups, that is, the copolymer of maltose-pendant monomer and a small amount of DMAPAA-Q was also synthesized by the similar method. The mole percent of DMAPAA-Q in polymerization process was chosen to be 5 mol% and 10 mol%. Hereafter, these synthesized copolymers are termed CP5 and CP10, respectively.
We prepared maltose-pendant polymer/mica hybrids by a solution intercalation method. Maltose-pendant poly- mer/mica hybrid solutions were prepared by mixing of a 5 wt% maltose-pendant polymer aqueous solution and a 5 wt% mica dispersion in a determined ratio, and after which sonic was irradiated for 5 min. Each obtained hybrid solution was cast on a corona-treated nylon-6 film. The thickness of solution was controlled by the wire bar (wire diameter = 0.75 mm). After drying at 100˚C for 30 s, the films were heat-treated at 210˚C for 15 s.
The morphology of maltose-pendant polymer/mica hybrids was studied by using XRD analysis and FE-SEM observation. The basal spacing of hybrids was evaluated by Rigaku diffractometer with CuKα radiation operated at 45 kV and 200 mA. Samples for XRD analysis were prepared by freeze-drying of hybrid solutions. The sur- faces of hybrids were observed by Hitachi SU8000 scanning electron microscope using an acceleration voltage of 5 kV. Samples for FE-SEM observation were prepared by drying of hybrid solutions at 100˚C in petri dishes. The OTR of hybrid-coated films was evaluated using Oxygen Permeation Analyzer 8001 (Systech Illi-
Synthesis of maltose-pendant polymer (MPP)
nois) at three relative humidity conditions, 0%, 50% and 90%.
The molecular weights of synthesized maltose-pendant polymers were determined by size exclusion chromato- graphy (SEC) using a Shodex SB-806M HQ column. The SEC calibration curve was prepared by a pullulan standard (Shodex STANDARD P-82). We used 10 mM lithium bromide (LiBr) aqueous solution as an eluent in order to prevent aggregations of the polymers. As shown in
The FE-SEM observation supports the result of XRD analysis.
XRD patterns of (a) mica powder; (b) MPP/Mica10; (c) CP5/Mica10; and (d) CP10/Mica10
. Molecular weights of maltose-pendant polymers
Compound code | Mw (×105) | Mn (×105) | Mw/Mn |
---|---|---|---|
MPP | 9.59 | 2.09 | 4.59 |
CP1 | 5.25 | 1.39 | 3.77 |
CP5 | 2.84 | 0.46 | 6.12 |
CP10a | - | - | - |
aThe peak of chromatogram was very weak, and molecular weights of CP10 couldn’t be evaluated.
FE-SEM images of the surfaces of (a) MPP/Mica10 hybrid; (b) CP5/Mica10 hybrid; and (c) CP10/Mica10 hybrid
telets. The surface of MPP/Mica10 is coarse, and which can be attributed to the phase separated structure as confirmed by XRD. On the other hand, the CP5/Mica10 and CP10/Mica10 reveal the smooth surfaces, suggest- ing that mica platelets are remarkably compatible with these positively charged copolymers. In conclusion, MPP/Mica10 belongs to a conventional phase separated composite, and we expect that exfoliated nanocompo- sites are obtained for CP5/Mica10 and CP10/Mica10 hybrids.
In general, oxygen gas barrier properties of polymer films are correlated to their crystallinity. Since water mo- lecules act as a plasticizer, their barrier performance decrease with the increase of humidity level. Therefore, we observed the OTR of prepared films at three relative humidity conditions, 0%, 50% and 90% (
First, we evaluated the OTR of non-coated nylon-6 film. The tolerable value of OTR in the food packaging application is considered to be 10 cm3·m−2·d−1·atm−1.
For the hybrid of MPP, we employed the loading of mica a little higher (10 wt% - 30 wt%), because this hy- brid took a conventional phase separated structure as confirmed in morphological studies. For simplification, the supersonic irradiation process of a mixed hybrid solution was omitted. As shown in
The barrier properties of polymer/clay hybrids are enhanced by finely dispersed impermeable clay particles. The extent of enhancement depends on the interfacial area between polymer matrix and clay particles. We in- troduced the cationic groups into maltose-pendant polymer in order to exfoliate negatively charged mica plate- lets individually. The morphological studies suggested that the exfoliated structures were obtained for these co- polymer hybrids.
. Oxygen transmission rate (OTR) of maltose-pendant polymer/mica hybrid-coated films
Coating agent | OTR in each humidity (cm3·m−2·d−1·atm−1) | ||
---|---|---|---|
0% | 50% | 90% | |
-a | 48.8 | 21.8 | 119 |
MPP | 0.93 | 14.2 | Over 70 |
MPP/Mica10 | 0.56 | 0.54 | 12.7 |
MPP/Mica20 | 0.19 | 0.59 | 9.52 |
MPP/Mica30 | 0.13 | 0.10 | 7.63 |
CP5 | 3.60 | 4.20 | 86.5 |
CP5/Mica5 | 0.50 | 1.40 | 81.4 |
CP5/Mica10 | 0.10 | 0.80 | 75.8 |
CP10 | 5.40 | 10.1 | 103 |
CP10/Mica5 | 2.40 | 5.30 | 101 |
CP10/Mica10 | 0.60 | 1.60 | 73.9 |
aNylon-6 film. The drying and heat-treatment processes were abbreviated.
ter than that of MPP coated film except for RH 50% condition. In addition, under RH 90% condition, these bar- rier properties were not improved by the hybridization with mica. For example, the OTR of CP5 coated film was 86.5 cm3·m−2·d−1·atm−1 under RH 90% condition, and that of CP5/Mica10 coated film was 75.8 cm3·m−2·d−1·atm−1. These results can be attributed to the lowering of crystallinty and the increase of hygroscopy brought by copo- lymerization with DMAPAA-Q. In contrast, under dry condition, the oxygen gas barrier property was remarka- bly improved by the hybridization with mica. For example, the OTR value of CP5 coated film, 3.60 cm3·m−2·d−1·atm−1 was reduced to 0.10 cm3·m−2·d−1·atm−1 by the hybridization with mica at only 10 wt% load- ing. Considering the corresponding values of MPP system (0.93 and 0.56 cm3·m−2·d−1·atm−1), we can conclude that the exfoliation of mica platelets enhances the gas barrier property efficiently under dry condition.
In this study, maltose-pendant polymer/mica nanocomposites were prepared, and their oxygen gas barrier properties were investigated. The XRD analysis and FE-SEM observation revealed that the hybrid of maltose-pen- dant polymer (homopolymer) was a conventional phase separated composite, and that nanocomposites with ex- foliated structures were achieved by using the copolymer of maltose-pendant monomer and DMAPAA-Q. This result indicates that introduction of cationic groups into polymer chains is an effective method for exfoliating negatively charged mica platelets individually. The oxygen gas barrier films were prepared by casting these conventional composite or nanocomposite on a nylon-6 film. Maltose-pendant polymer improved the oxygen gas barrier property under dry condition. The barrier property under wet condition was improved by the hybri- dization with mica. The OTR at RH 90% condition was reduced to 7.63 cm3·m−2·d−1·atm−1 at 30 wt% mica loading, indicating that this material has a potential to be applied to the food packaging field. The barrier proper- ties of copolymers were not better than that of maltose-pendant polymer. However, the effects of dispersion at nano level were confirmed under dry condition.