Introduction

Plastics are used for multiple purposes as parts of automobiles, home electrical appliances, food packaging materials, and medical equipment and thus constitute essential materials in our lives. Reinforcing materials are often added to these plastics to improve their mechanical properties. Common reinforcing materials include glass and carbon fibers; hence, composite materials acquire the strength and thermal dimensional stability that plastics cannot attain on their own. However, as the energy demand for the production and discarding of these reinforcing materials is high, plastic reinforcement using environmentally friendly materials has become a priority toward the implementation of a low-carbon society.

In recent years, cellulose nanofibers (CNFs) have been used as a natural carbon-neutral reinforcing material. In particular, wood-derived CNFs have a characteristic shape and are ~3 nm in width and several micrometers in length. They have been demonstrated to have excellent mechanical and thermomechanical properties, with high strength (2‒6 GPa) [1, 2], high elastic moduli (130‒150 GPa) [3,4,5], and low thermal expansion coefficients (4‒6 ppm K−1) [6, 7]. Taking advantage of these characteristics of CNFs, ongoing research has been extensively focused on utilizing them as a reinforcing material for plastics since the mid-1990s [8,9,10]. To fully elicit the reinforcing effect of CNFs, CNFs must be homogenously dispersed in a composite material. However, obtaining a homogenous composition of CNFs and commodity plastics has been difficult due to the high interfacial energy. Therefore, the composition difficulty poses the biggest challenge for the production of such materials.

To date, we have sought to develop homogeneously mixed CNF/polymer composites using a CNF prepared through chemical pretreatment termed 2,2,6,6-tetramethylpiperidinyl-1-oxyl (TEMPO)-mediated oxidation [11, 12]. TEMPO-mediated oxidation is a chemical reaction that enables selective conversion of primary hydroxy groups into carboxylate groups in water. The oxidation selectively introduces carboxylate groups onto the surface of cellulose microfibrils. The increased osmotic pressure between the fibrils and mild mechanical treatment in water allow the preparation of CNFs with nanosized widths and good colloidal stability in water. Moreover, tailoring the chemical structure of the carboxy groups effectively enables the dispersion of CNFs in various organic solvents [13,14,15]. Homogeneous CNF/polymer composites can be prepared by drying a mixture of a plastic and CNF dispersions in organic solvents [14, 16, 17]. However, such a process is highly time and energy consuming.

In this review, we sought to develop a homogenous composite of CNFs and a hydrophobic plastic using an aqueous solution process, which does not require organic solvents or melt blending procedures. CNFs are known to serve as an excellent emulsifier and form stable Pickering emulsions [18,19,20]. Pickering emulsions are emulsions stabilized by solid particles. Compared to surfactant molecules, the solid particles more strongly adsorb at liquid/liquid interfaces. Therefore, Pickering emulsions generally show better stability than emulsions stabilized by surfactants. In the present study, a CNF-stabilized monomer-in-water emulsion was used as a starting point to design a CNF/polymer composite structure [21]. Several studies on polymer composite preparation through Pickering emulsions have been reported, where nanocelluloses [22, 23], microfibrillated lignocellulose [24], or chitin nanofibrils [25,26,27] were used as stabilizers. Furthermore, we report the synthesis of core-shell microparticles using this Pickering emulsion as a template [28].

CNF/polymer nanocomposite film

In this study, polystyrene (PS) was used as a matrix. First, an aqueous dispersion of CNFs was mixed with styrene monomers, into which an initiator was dissolved. This mixture then underwent ultrasound treatment, which resulted in the formation of a CNF-stabilized styrene-in-water emulsion (Fig. 1a). As the interfacial free energy between styrene and water is high, usually, styrene and water ultimately undergo phase separation without being homogenously mixed. In contrast, in the present system, CNFs were adsorbed onto the water/styrene interface, metastabilizing the system. The emulsion using solid particles as a dispersion stabilizer is generally termed a Pickering emulsion. The Pickering emulsion in this work was quite stable, even when it was kept at room temperature for more than a week. The monomer droplets were stably dispersed in water, retaining the size distribution. The repulsive force between the droplets is mainly caused by the osmotic pressure due to the carboxylate groups on the surface of TEMPO-oxidized CNFs.

Fig. 1
figure 1

Schematic illustration of the synthesis of a CNF/PS composite film. a Monomer-in-water emulsion stabilized by CNFs, b dispersion of CNFs and PS nanoparticles in water, c CNF/PS nanoparticle composite sheet, and d CNF/PS composite film. Copyright 2017, American Chemical Society

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The obtained emulsion was heated at 70 °C to polymerize the monomer. As a result, in the polymerization process, the structure of the microemulsion broke down, and a structure in which PS nanoparticles were homogenously dispersed in an aqueous dispersion of CNFs (Fig. 1b) was formed. This polymerization mechanism resembles the method termed dispersion polymerization [29,30,31], where polymerization occurs in poor solvents. Scanning electron microscopy showed that during the course of polymerization, PS nanoparticles were squeezed out from monomer droplets and deposited in the CNF aqueous dispersion.

Via filtration of the dispersion through membrane filters, CNF/PS nanoparticle composite sheets can be prepared (Fig. 1c). The PS yield was 84%, and the CNF volume fraction within the sheet calculated from the yield was 7%. Observation of the sheets using electron microscopy revealed the formation of composites of CNFs and PS nanoparticles with diameters of ~150 nm (Fig. 2). The PS nanoparticles were observed to homogeneously form composites with CNFs both on the surfaces and in the interior of the sheets. Importantly, nanocompositing of PS and CNFs was achieved using an aqueous solution process. As noted above, fabricating homogeneous CNF/polymer composites is time and energy consuming. In contrast, the nanocomposite sheets obtained with the present method can be easily formed by homogenously depositing PS nanoparticles in a CNF network in water, followed by their collection through filtration. Measurement based on a size exclusion chromatography-multiangle laser-light scattering detector revealed that the polymerized PS was composed of straight chains, with an average molecular weight of 1 560 000 (polydispersity index of 1.6), indicating an extremely high degree of polymerization.

Fig. 2
figure 2

a Photograph, be SEM images, and f schematic illustration of a PS/CNF composite with 12% w/w CNFs before melt pressing. b, c Film surface, d edge, and e side surface. Copyright 2017, American Chemical Society

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The resulting CNF/PS nanoparticle sheets had a highly porous structure and therefore low transparency. Nonetheless, they formed transparent CNF/PS composite films following a 30 s hot press process at 160 °C (Fig. 1d). After this, the PS nanoparticles formed films due to the glass transition (Fig. 2e, f). The light transmittance rate at 600 nm was observed to be 88%; composites were formed without serious loss of transparency of the PS film (90% at 600 nm) (Fig. 3a). Although a transparent film can be obtained here, a heating process is necessary after the polymerization. In future work, development of a process without heating may be needed for commercial use. Tensile testing of the films demonstrated that the addition of CNFs increased the Young’s modulus and strength (Fig. 3b). However, the elongation at break was noted to be reduced with the addition of CNFs. In simple terms, although the material became stiff and strong, it also became quite brittle. We assumed that this was due to the poor interactions at the CNF-PS interface. This is known to be a common property of CNF-based polymer composites, and to reduce their brittleness, the interfacial interactions must be improved through modification of the surface chemical structures of CNFs [14, 17]. Furthermore, the thermal dimensional stability was shown to be improved by the formation of a network of CNFs in the PS matrix (Fig. 3c). This improvement was particularly striking at temperatures greater than 100 °C, which corresponds to the glass transition region of PS; the disadvantage of the propensity of PS to stretch when heated was successfully compensated by the addition of CNFs. These tensile and thermomechanical properties were shown to be almost comparable to those of CNF/PS composites [16] prepared from organic solvents, indicating that the use of the aqueous solution process in the present study almost achieved the ideal CNF dispersion in PS.

Fig. 3
figure 3

Properties of a PS/CNF composite film with 12% w/w CNFs after melt pressing. a UV–vis transmittance spectra, b stress–strain curves, and c thermal expansion behavior of the PS/CNF composite and PS films. Copyright 2017, American Chemical Society

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Cellulose nanofiber-shelled polymer microparticles

Using the aforementioned CNF/monomer Pickering emulsion and controlling the polymerization conditions, CNF/polymer microparticles that preserved the droplet shape of the emulsion (Fig. 4) were successfully prepared. Goi et al. reported that the interfacial tension between oil and water plays a significant role in stabilizing CNF-based Pickering emulsions [32]. In preparing CNF/polymer composites through emulsion templating, the interfacial tension between the monomer liquid and water is also an important factor in controlling the composite structure. In the present study, we used divinylbenzene as a monomer in place of styrene. The average diameter of the obtained microparticles was ~3 µm, showing that the initial droplet size in the emulsion was maintained. Furthermore, as the surfaces of these microparticles were densely covered with TEMPO-oxidized CNFs, which have carboxylate groups on the surfaces, the zeta potential of the microparticles was shown to be ~−50 mV. Therefore, the microparticles exhibited good dispersibility in water. Observation of the surfaces of microparticles using scanning electron microscopy revealed that the surfaces were densely covered with the CNFs (Fig. 5b–d). Further observation of cross sections revealed no voids in the interior of the particles, with the interior being uniformly filled with polymers. Based on the scanning electron microscopy results, the thickness of the CNFs on the surface of the particles was estimated to be ~8 nm (Fig. 5f and g). Similar experiments were conducted using other CNFs, such as microfibrillated cellulose, for the preparation of microparticles. However, the particles had a broader size distribution with low dispersibility in water. When water-soluble carboxymethyl cellulose was used, the resulting emulsion had poor structural stability, partially breaking down in the course of polymerization. Therefore, TEMPO-oxidized CNFs have been found to be suitable for preparing microparticles with good dispersibility and a narrow size distribution.

Fig. 4
figure 4

Schematic illustration of the synthesis of CNF-shelled microparticles at a 10:90 ratio (o/w). CNF-stabilized Pickering monomer-in-water emulsion (center), CNF-shelled microparticle dispersion in water, and size distribution of CNF/polymer microparticles determined by dynamic light scattering analysis showing a median diameter of 3.0 μm (right). Copyright 2019, The Royal Society of Chemistry

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Fig. 5
figure 5

a Illustration and bd SEM images of CNF-shelled microparticles and surface (bottom right). e Illustration and f, g SEM images of the cross section of microparticles embedded in acrylic resin. Black arrows indicate the CNF shell. Copyright 2019, The Royal Society of Chemistry

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The molecular adsorption behavior of CNFs on the surfaces of particles was investigated using methylene blue (MB) as a cationic dye (Fig. 6a–c). At pH 7.0, the CNFs were shown to have a higher MB adsorption than at pH 2.5. This was assumed to occur because the TEMPO-oxidized CNFs present on the particle surfaces had a large number of carboxylate groups: At pH 2.5, the carboxylate groups on the surfaces of the CNFs could not form an ionic bond with MB, and therefore, physical adsorption was thought to be the only adsorption mechanism at work. On the other hand, at pH 7.0, these groups could interact with MB through not only physical adsorption but also ionic bonding. Thus, the obtained CNF-shelled microparticle results indicated that the equilibrium adsorption isotherm was dependent on the pH conditions. Furthermore, the experimental data at pH 2.5 were fitted with the Langmuir model, revealing good correspondence at low concentrations (Fig. 6c). In other words, our results suggested that theoretically estimated single-layer adsorption occurred at low concentrations.

Fig. 6
figure 6

Adsorption behavior of methylene blue (MB) on CNF-shelled microparticles. a Chemical structure of MB. b Equilibrium adsorption isotherm. c Langmuir isotherms of MB on microparticles at 23 °C, where the dotted lines are obtained by fitting the Langmuir model. d Demonstration of MB adsorption before (left), during (center), and after (right) filtration, where 100 mg of CNF-shelled microparticles are retained in the 0.2 μm PTFE membrane filter. e Light transmittance spectrum and f photograph of the MB solution before and after filtration. g Repeated adsorption/desorption behavior at pH 7.0 and 2.5 through filtration. h Chemical structure of acridine orange hydrochloride. i Confocal laser scanning microscopy image of CNF-shelled microparticles, where surfaces are stained with acridine orange. Copyright 2019, The Royal Society of Chemistry

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To take advantage of this adsorption characteristic, filtration was used to perform MB adsorption experiments (Fig. 6d). MB adsorption on the particle surfaces occurred very quickly: ~99% of MB was adsorbed when the MB solution (5 mg L−1) was passed through at ~100 mL min−1 and pH 7.0 (Fig. 6e, f). Moreover, MB was washed with phosphate buffer (pH 2.5) once adsorbed and was almost entirely removed, which allowed us to repeatedly perform adsorption experiments (Fig. 6g).

To visualize this molecular adsorption behavior, a confocal laser microscopic observation was carried out. Acridine orange (Fig. 6h) was used as the fluorescence dye. Our observations revealed that acridine orange did not exist in the interior of the particles and was selectively adsorbed only on the surfaces of the particles (Fig. 6i). The acridine orange layer appeared thicker than the CNF layer observed in SEM. This was assumed to be due to the resolution capability of the confocal laser microscope being ~200 nm and its scanning depth being ~0.7 µm.

Summary

By taking advantage of the high potential of CNFs as an emulsifier, we successfully produced homogenous composite films of CNFs and a water-insoluble plastic. As these preparation processes do not require organic solvents or high-heat processing, they are considered to be highly environmentally friendly and could also be achieved at a lower cost than the generation of conventional CNF-based composites. We expect the CNF/polymer nanocomposite film to be utilized as a transparent material with excellent mechanical properties and low thermal expansion coefficients. Moreover, core-shell microparticles, whose shell and core are CNFs and a polymer, respectively, can be prepared from the Pickering emulsion. As the microparticles are covered with plant-based CNFs, they are expected to be utilized as functional microparticles. The biocompatibility of the CNF shells could open up new possibilities for biomedical or cosmetic applications. Moreover, the particles could be used for environmental applications by utilizing the carboxy groups of the CNFs.