Manufacture of Highly Transparent and Hazy Cellulose Nanofibril Films via Coating TEMPO-Oxidized Wood Fibers
1
Jiangsu Co-Innovation Center for Efficient Processing and Utilization of Forestry Resources, Nanjing Forestry University, Nanjing 210037, Jiangsu, China
2
School of Chemical & Biomolecular Engineering and Renewable Bioproducts Institute, Georgia Institute of Technology, Atlanta, GA 30318, USA
*
Author to whom correspondence should be addressed.
Nanomaterials 2019, 9(1), 107; https://doi.org/10.3390/nano9010107
Submission received: 16 November 2018
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Revised: 25 December 2018
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Accepted: 9 January 2019
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Published: 16 January 2019
(This article belongs to the Special Issue Cellulose Nanomaterials)
Abstract
:Traditionally, inorganic nanoparticles (SiO2, TiO2) have been utilized to tune the optical haze of optoelectronic devices. However, restricted to complex and costly processes for incorporating these nanoparticles, a simple and low-cost approach becomes particularly important. In this work, a simple, effective, and low-cost method was proposed to improve optical haze of transparent cellulose nanofibril films by directly depositing micro-sized 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO)-oxidized wood fibers (“coating” method). The obtained films had a high total transmittance of 85% and a high haze of 62%. The film samples also showed a high tensile strength of 80 MPa and excellent thermal stability. Dual sides of the obtained films had different microstructures: one side was extremely smooth (root-mean-square roughness of 6.25 nm), and the other was extremely rough (root-mean-square roughness of 918 nm). As a reference, micro-sized TEMPO-oxidized wood fibers and cellulose nanofibrils were mixed to form a transparent and hazy film (“blending” method). These results show that hazy transparent films prepared using the “coating” method exhibit superior application performances than films prepared using the “blending” method.
1. Introduction
Tuning optical performances including transparency and optical haze play a critical role in preparing optoelectronic devices with varying optical requirements. For outdoor display [1] or solar cells [2,3], high transmittance and high optical haze are essential. Optical haze is defined as the ability to scatter incident light, presenting as translucent or opaque. In general, methods for preparing hazy transparent films can be classified into two types: the particle-diffusing type, which relies on the transparent particles inside the transparent films to scatter light, and the surface-relief type, which relies on microstructures on the surface of the transparent films to scatter light [4,5]. For the particle-diffusing type, transparent SiO2 and TiO2 nanoparticles and silver nanowires have been utilized for hazy transparent film fabrication due to the difference in the refractive coefficient between transparent substrates and inorganic nanoparticles [6,7]. For the surface-relief type, polydimethylsiloxane (PDMS) replica molding [8], the silver halide sensitized gelatin method [9], holographic recording [10], the 3D diffuser lithograph [11], photofabrication [12], hot embossing [13], and roller extrusion [4] have been developed to replicate the microstructures onto the surface of plastic films. However, most methods employ complex processes and require expensive equipment.
As a side effect of the incorporation cost, novel “green” methods have attracted much attention in recent years. Recently, transparent papers with high haze have attracted abundant attention as a potential bulk substrate for fabricating flexible transparent devices. Flexible and transparent films made of cellulose fibers or cellulose nanofibers are emerging as a substrate in optical electronic devices. Fang et al. (2013) reported a low-cost method for the preparation of a transparent substrate with better shape stability via filling cellulose nanofibrils (CNF) into opaque mesoporous wood fiber-based paper [14]. Zhu et al. (2015) achieved >90% total transmittance and >90% light scattering when the microfibers were in situ, nanowelded in ionic liquid [15]. An effectively light coupling and antiglare effect was demonstrated for the application of Organic Light Emitting Diode (OLED) lighting. Nogi et al. (2017) introduced a hazy transparent nanopaper consisting of cellulose nanofibers and some microsized cellulose fibers with a total transmittance of 89.3–91.5% and haze values of 4.9–11.7% [16]. In these methods, the highly optical haze was mainly achieved through the serious light scattering of the micro-sized fibers within the transparent films, which is similar to particle-diffusing type. Herein, the surface-relief type was presented to fabricate microstructures onto 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO)-oxidized cellulose nanofibril (TOCNs) film surfaces to achieve high optical haze. Micro-sized TEMPO-oxidized wood fibers were utilized to coat on TOCN film surfaces to achieve surface-relief microstructures.
In the present study, a highly transparent and hazy TOCN film was fabricated by a simple coating of micro-sized fibers. Dual sides of the hazy transparent films had different microstructures: one side was smooth and the other was rough. The serious light scattering induced by the rough surface endows a high haze for transparent TOCN films. The extremely smooth surface with root-mean-square (RMS) roughness of 6.25 nm is suitable for continuous conducting thin layer depositing. As a reference, micro-sized TEMPO-oxidized wood fibers and cellulose nanofibrils were mixed to form a hazy transparent film (“blending” method). The influence of preparation methods on the transmission haze and surface morphology was investigated.
2. Materials and Methods
2.1. Materials
Softwood bleached kraft pulp was used as the original cellulose, purchased from Suzanno. TEMPO-oxidized wood fibers (TOWFs) and TEMPO-oxidized cellulose nanofibrils (TOCNs) were prepared according to previous reports [17,18]. According to previous measurements, the size of TOWFs was around 63.0 μm length and 18.6 μm width. The TOCNs used in this study had a surface carboxylate content of 1.633 mmol/g with a diameter of 6–8 nm and a length around 500 nm.
2.2. Fabrication of Hazy Transparent Films via “Blending” Method
The mixture of TOCNs/TOWFs with the mass ratio of 10/3 was prepared from a TOCNs suspension (0.5 wt %) and a TOWFs suspension (0.5 wt %). The obtained mixture was carefully mixed to ensure good dispersion and to prepare hybrid films via the solution-casting method. The solution-casting method was conducted by pouring the mixture slurry into plastic Petri dishes (diameter 60 mm) and dried at room temperature for a few days until a dried film formed. The obtained dried films were denoted as TOCNs/TOWFs-B films with the basis weight of 65 g/cm2.
2.3. Fabrication of Hazy Transparent Films via “Coating” Method
The TOCNs suspension was diluted to approximately 0.5 wt % and stirred at room temperature overnight to guarantee the uniform dispersion. Then, the homogeneous 0.5 wt % TOCNs aqueous suspension in a plastic petri dish (diameter 60 mm) was dried until a thin TOCNs gel formed. Continuously, the TOWFs suspension with 0.5 wt % was directly coated onto the TOCNs gel and dried under room temperature until a dried film formed. The obtained hazy transparent films were denoted as TOCNs/TOWFs-C films with the basis weight of 65 g/cm2. The mass ration of the TOCNs/TOWFs was still 10/3 to ensure comparability.
2.4. Analysis
2.4.1. Surface and Cross-Sectional Morphology
Surface and cross-sectional morphology were analyzed by field emission scanning electron microscope (FE-SEM, JSM-7600F, JEOL Ltd., Tokyo, Japan) and atomic force microscopy (AFM, Dimension Edge, Bruker, Hamburg, Germany). For FE-SEM characterization, film samples were mounted on the well-polished metal stub and then coated with gold, using Agar HR sputter coater. For AFM measurements, film samples were placed on the mica plate. Images were acquired in tapping mode in air using a silicon cantilever, which was in vibrating mode at 160–225 kHz.
2.4.2. Optical Properties
The light transmittance and optical haze were measured using a Ultraviolet/Visible/Near infrared (UV/VIS/NIR) spectrophotometer (Lambda 950, PerkinElmer, Waltham, MA, USA) at a wavelength range from 400 nm to 1100 nm according to the ASTM1003-13 standard method [19].
2.4.3. Thermal Properties
Thermal properties of film samples were analyzed using a thermos-gravimetric analyzer (TGA) (Q5000IR, TA Instruments, New Castle, DE, USA). About 5 mg was heated from 35 °C to 600 °C with a heating rate of 10 °C/min under an inert atmosphere of nitrogen at a gas flow of 20 mL/min.
Thermal stabilities of the film samples under air atmosphere were tested in a muffle furnace. The samples were heated from room temperature to 600 °C while the morphology of the film samples was observed.
2.4.4. Mechanical Properties
Mechanical analysis of film samples was carried out using a tensile tester (H25KT, Tinius Olsen, Horsham, PA, USA) with a 500 N load cell at 1 mm/min at room temperature, according to ASTM D638-03. The samples had a typical dimension of 5 mm in width and 40 mm in length. Prior to the test, all samples were pre-conditioned at 50% relative humidity (RH), 23 °C for at least 24 h. Three measurements were carried out for each sample.
2.4.5. Resistance to Corrosive Chemicals Property
The chemical stability of film samples in diluted hydrochloric acid (0.1 mol/L, pH = 1.0) was estimated by investigating the mechanical properties of film samples before and after treatment. The samples had a typical dimension of 5 mm in width and 40 mm in length.
2.4.6. Resistance to Photodegradation Property
The resistance to photodegradation of film samples under UV radiation was estimated by investigating the mechanical properties of film samples before and after treatment. The samples had a typical dimension of 5 mm in width and 40 mm in length.
3. Results and Discussion
3.1. Optical Properties
In comparison with micro-sized fibers, TOCNs with nano-sized dimensions have extremely low scattering for the visible light. The reason for this phenomenon is that the dimension of TOCNs (6–8 nm) is much smaller than the wavelength of the visible light (390–760 nm). The compact structure and low porosity weakens the light scattering between fibers and air, endowing high transparency for the TOCN films [20]. TOCN films, as a bulk optical material for optoelectronics, have attracted abundant attention due to their excellent optical transmittance [21]. However, their low haze is not suitable for preparing some optoelectronics such as outdoor display and solar cells, which need high optical haze. Herein, micro-sized TOWFs with strong light scattering were used to improve optical haze of the TOCN films via the “blending” method or “coating” method. The visual appearance of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films in close contact with a color pattern is shown in Figure 1a–c, respectively. It can be seen that all the films had high transparency, and the pattern under the transparent films can be clearly observed by human eyes. These results indicated that the existence of TOWFs has a weak influence on the transparency of TOCNs/TOWFs hybrid films. As shown in Figure 2a, all film samples exhibited high transmittance, ranging from 83–89%.
Transparency is a significant optical parameter for most transparent electronic devices [22]. However, for some specific devices such as indoor and outdoor displays and solar cells, optical haze is also an important indicator that cannot be ignored. As the Figure 1d–f shows, the pattern behind the TOCN films was clearly observed, while for TOCNs/TOWFs-B and TOCNs/TOWFs-C films, the bottom patterns look obscure. According to the optical haze data (Figure 2b), the neat TOCN films had an extremely low optical haze of 3.8% at 600 nm. After incorporating TOWFs, the composite films exhibited a high optical haze of 50% for TOCNs/TOWFs-B and 62% for TOCNs/TOWFs-C films. This may be due to TOWFs having prominent light scattering, which had been confirmed by previous studies [23]. Simultaneously, TOCNs/TOWFs composite films had a rougher surface than neat TOCN films. The rough surface caused substantial light scattering, which led to a high transmission haze [24,25]. In comparison to the “blending” method, the hazy film prepared by the “coating” method exhibited higher optical haze. The higher transmission haze could be ascribed to higher surface roughness.
Figure 3 illustrates the mechanism of light scattering for TOCNs/TOWFs composite films. For the “blending” method (similar to particle-diffusing type), high optical haze was mainly achieved through the serious light scattering of the micro-sized fibers within the transparent films (Figure 3a). For the “coating” method (similar to surface-relief type), the forming of the surface-relief microstructures via the deposition of micro-sized TOWFs induced strong light scattering and endowed high optical haze for the transparent films (Figure 3b).
3.2. Surface and Cross-Sectional Morphology
As shown in Figure 4a,b, two types of TOCNs/TOWFs hybrid films had a condensed structure and no obvious holes, which endowed a high total transmittance for these transparent films [26]. For the TOCNs/TOWFs-B films, TOCNs and TOWFs were tightly intertwined together to form a uniform and compact structure. As the top-view SEM images show, only a few micro-sized fibers were observed on the surface of the hybrid films. For the TOCNs/TOWFs-C films, TOWFs were directly coated on the TOCN film surface to form surface-relief morphology. Additionally, a randomly intertwined TOWFs network was observed clearly in the top-view SEM images (Figure 4b). To further investigate the surface roughness, atomic force microscopy (AFM) was used to analyze TOCNs/TOWFs hybrid film surfaces. The particular values are shown in Table 1. The dual sides of the TOCNs/TOWFs-B films had a similar surface roughness of 279 nm (Figure 4c). The TOCN films consisting nano-sized TOCNs, prepared by the solution-casting method, had an extremely smooth surface with RMS of 6.25 nm. Then, the TOWFs were coated on the one side of the TOCN films to form a rough TOWF layer with RMS of 918 nm, and the other one was kept smooth. Hence, the dual sides of the TOCNs/TOWFs-C films had different surface morphologies; one side was smooth, and the other one was rough. The rough surface endowed high optical haze for the transparent films, and simultaneously the smooth surface was suitable for continuous conductive thin layer (~100 nm) depositing. Under the same addition of TOWFs, the hazy film prepared by “coating” method exhibited a rougher surface morphology than the “blending” method. As our previous study showed, the rough surface caused substantial light scattering, which led to a higher optical haze. Hence, the TOCNs/TOWFs-C film had a higher optical haze than TOCNs/TOWFs-B film. As the TOCNs and TOWFs were tightly intertwined with each other, the blade-cut cross-sections were very smooth, and the internal structures could not be clearly observed (Figure 4e,f). The dense structure endowed TOCNs/TOWFs hybrid film’s high light transmittance.
3.3. Thermal Property
TOCN films are more suitable for manufacturing transparent electronic devices than common plastic materials due to their excellent thermal stability and degradation behaviors [27]. Thermal stability is one of the most crucial properties of polymer materials, which can influence the processing and service life performance of these materials [28,29]. Thermogravimetric analysis (TGA) and derivative thermogravimetry (DTG) curves of the transparent films are presented in Figure 5, and the corresponding characteristic data are listed in Table 2. All the film samples had a small weight loss in the low temperature (<100 °C), due to the evaporation of absorbed water. The thermal transition of the films includes the tow phase: (1) the decomposition of carboxyl groups occurred at about 250 °C and (2) the decomposition of cellulose occurred at about 320 °C [30]. Among the three samples, the Stage I maximum thermal degradation temperature (Tmax) of the TOCN films occured at 244 °C with a maximum weight loss rate (WLRmax) of 4.7%/min, and the corresponding data for Stage II are 319 °C and 4.7%/min. The thermal stability of TOCNs/TOWFs-B and TOCNs/TOWFs-C films (“blending” method and “coating” method) is similar to that of TOCN films. TOCNs/TOWFs-B and TOCNs/TOWFs-C films only had a higher char yield than neat TOCN films. Although the thermal stability of the TOCNs/TOWFs hybrid films (degradation at around 250 °C) was lower than the natural cellulose fibers (degradation at around 300 °C [31]), it was still higher than most of the flexible plastics, such as polyethylene terephthalate (PET), polyethylene naphthalate (PEN), and polycarbonate (PC) [32].
To further demonstrate the thermal stability of the samples, TOCN films and TOCNs/TOWFs films were tested in a muffle furnace while the morphology of the film samples before and after thermal treatment was observed. The morphology of the film samples is shown in Figure 6. When temperature reached 200 °C, the morphology of the film samples remained unchanged. As the temperature was further increased, the film samples began to carbonize and eventually burned to ash. These results indicated that the hazy and transparent film has an excellent morphology stability under a relatively low temperature (less than 200 °C).
3.4. Mechanical Property
The mechanical properties of transparent substrates play a significant role in flexible and transparent devices [33]. A comparative study of the mechanical properties of TOCNs/TOWFs hybrid films prepared by different fabrication methods was carried out. The tensile properties of film samples are listed in Table 3. Mechanical properties relate directly to the single fibril and interfibrillar bonding, which also could be affected by the fabrication processes. The TOCN films, comprised of nano-scale TOCNs, exhibited a remarkably high strength of 92 MPa, high Young’s modulus of 9.81 GPa due to the tightly intertwined nanofibrillar network, and numerous hydrogen bonds [34]. In comparison with TOCNs, TOWFs had a bigger dimension and smaller specific surface area, resulting in a loose stricture for TOCNs/TOWFs hybrid films. Hence, TOCNs/TOWFs-B and TOCNs/TOWFs-C films (“blending” method and “coating” method) showed a lower tensile strength of 75 MPa and 80 MPa, respectively, than neat TOCN films. However, the stiffness of the TOCNs/TOWFs-B and TOCNs/TOWFs-C films was greater than neat TOCN film. In general, the tensile property is still much higher than those of common synthetic polymer films [35].
3.5. Resistance to Corrosive Chemicals and Photodegradation Properties
It is very important to identify the stability of film samples in extreme conditions when they are applied to outdoor displays or solar cells. The corrosion- and photodegradation-resistant properties of the film samples were estimated by measuring the mechanical properties of the film samples after dilute acid or UV radiation treatments. Figure 7 shows the mechanical properties of the film samples after dilute acid (0.1 mol/L, pH = 1.0) or UV radiation treatments for 24 h. In the case of immersion in 0.1 mol/L hydrochloric acid, the tensile strength of TOCNs/TOWFs-C films decreased from 80 MPa to 58 MPa; simultaneously, Young’s modulus decreased from 15.30 GPa to 10.18 GPa. These results indicated that the mechanical property of the TOCNs/TOWFs-C films was reduced by immersion in the acid solution. In the case of UV radiation for 24 h, the mechanical property was kept almost constant. These results indicated that the TOCNs/TOWFs-C films were not acid-resistant but ultraviolet radiation-resistant. As a reference, the corrosion- and photodegradation-resistant properties of PET films were studied. In the case of dilute acid treatment or UV radiation for 24 h, the mechanical properties of the PET films were kept almost constant. Hence, in comparison with traditional PET plastic films, TOCNs/TOWFs-C films are not acid-resistant, which needs to be further improved to meet the requirements of the outdoor application.
4. Conclusions
In this study, highly transparent and hazy films (85% total transparency and 62% optical haze at 600 nm wavelength) were prepared by coating micro-sized TEMPO-oxidized fibers onto TOCN film surfaces. The TOCNs/TOWFs-C films had dual sides with different microstructures: one side was smooth (root-mean-square roughness of 6.25 nm) and the other was rough (root-mean-square roughness of 918 nm). The rough surface endowed a high haze for films without seriously decreasing total transmission. The optical haze property of TOCNs/TOWFs-C films was exceptionally good, and much superior to TOCNs/TOWFs-B prepared by blending TOCNs and TOWFs. In addition, the smooth surface of TOCNs/TOWFs-C was more suitable for the conductive thin layer depositing than TOCNs/TOWFs-B films. Both TOCNs/TOWFs-B and TOCNs/TOWFs-C films exhibited good thermal stability and mechanical properties. The resulting films also showed excellent ultraviolet radiation resistance but not acid resistance. Our work provided insight into the preparation of high performance transparent and hazy films for the fabrication of green optoelectronics.
Author Contributions
W.Y. and H.D. conceived and designed the experiments; W.Y. and L.J. performed the experiments and analyzed the data; W.Y. wrote the original paper; and W.L. and H.D. edited the manuscript.
Funding
This study was funded by the Introduction of Advanced International Project of Forestry Science and Technology (Grant Number: 2015454), the Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD), and the Doctorate Fellowship Foundation of Nanjing Forestry University.
Acknowledgments
The authors thank Jing Yang and Vincent Li for providing valuable guidance on the use of equipment.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
(a–c) Visual appearance of 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO)-oxidized cellulose nanofibril (TOCN) films, TOCNs/ TEMPO-oxidized wood fibers B (TOWFs-B), and TOCNs/TOWFs-C films in close contact with underneath color pattern. (d–f) Digital photographs of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films were lifted up to 6 cm above color pattern.
Figure 1.
(a–c) Visual appearance of 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO)-oxidized cellulose nanofibril (TOCN) films, TOCNs/ TEMPO-oxidized wood fibers B (TOWFs-B), and TOCNs/TOWFs-C films in close contact with underneath color pattern. (d–f) Digital photographs of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films were lifted up to 6 cm above color pattern.
Figure 2.
(a) Transmittance of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films and (b) Optical haze of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
Figure 2.
(a) Transmittance of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films and (b) Optical haze of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
Figure 3.
Mechanism of light scattering of (a) TOCNs/TOWFs-B films and (b) TOCNs/TOWFs-C films.
Figure 4.
(a) FE-SEM image of TOCNs/TOWFs-B films, (b) FE-SEM image of TOCNs/TOWFs-C films, (c) 3D AFM image of TOCNs/TOWFs-B films surface, (d) 3D AFM image of the rough surface of TOCNs/TOWFs-C films, (e) cross-sectional structure of TOCNs/TOWFs-B films, and (f) cross-sectional structure of TOCNs/TOWFs-C films.
Figure 4.
(a) FE-SEM image of TOCNs/TOWFs-B films, (b) FE-SEM image of TOCNs/TOWFs-C films, (c) 3D AFM image of TOCNs/TOWFs-B films surface, (d) 3D AFM image of the rough surface of TOCNs/TOWFs-C films, (e) cross-sectional structure of TOCNs/TOWFs-B films, and (f) cross-sectional structure of TOCNs/TOWFs-C films.
Figure 5.
Thermogravimetric analysis (TGA) (a) and derivative thermogravimetry (DTG) (b) curves of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
Figure 5.
Thermogravimetric analysis (TGA) (a) and derivative thermogravimetry (DTG) (b) curves of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
Figure 6.
Thermal stability of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films under air atmosphere.
Figure 6.
Thermal stability of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films under air atmosphere.
Figure 7.
Mechanical properties of the TOCNs/TOWFs-C films and PET films without treatment, with acid or UV radiation treatment, (a) Tensile strength, (b) Young’s modulus.
Figure 7.
Mechanical properties of the TOCNs/TOWFs-C films and PET films without treatment, with acid or UV radiation treatment, (a) Tensile strength, (b) Young’s modulus.
Table 1.
Thickness, surface roughness, and optical properties of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
Table 1.
Thickness, surface roughness, and optical properties of TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
| Sample | Thickness (μm) | Upper Surface Roughness (nm) | Bottom Surface Roughness (nm) | Transmittance (%) | Haze (%) |
|---|---|---|---|---|---|
| TOCN films | 34.6 | 6.25 | 6.25 | 89 | 3.8 |
| TOCNs/TOWFs-B films | 69.2 | 279 | 279 | 83 | 50 |
| TOCNs/TOWFs-C films | 80.5 | 918 | 6.25 | 85 | 62 |
Table 2.
TGA and DTG data measured at a heating rate of 10 °C/min.
| Sample | Stage I | Stage II | CY (%) | ||
|---|---|---|---|---|---|
| Tmax (°C) | WLRmax (%/min) | Tmax (°C) | WLRmax (%/min) | ||
| TOCN films | 244 | 4.7 | 319 | 4.7 | 12.7 |
| TOCNs/TOWFs-B films | 250 | 4.8 | 318 | 5.7 | 22.0 |
| TOCNs/TOWFs-C films | 250 | 4.6 | 327 | 5.9 | 28.7 |
Table 3.
Tensile properties of the polyethylene terephthalate (PET) films, TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
Table 3.
Tensile properties of the polyethylene terephthalate (PET) films, TOCN films, TOCNs/TOWFs-B films, and TOCNs/TOWFs-C films.
| Sample | Tensile Strength (MPa) | Young’s Modulus (GPa) | Strain at Break (%) |
|---|---|---|---|
| TOCN films | 92 ± 6.5 | 9.81 ± 1.3 | 0.98 ± 0.2 |
| TOCNs/TOWFs-B films | 75 ± 3.5 | 10.49 ± 2.1 | 0.75 ± 0.1 |
| TOCNs/TOWFs-C films | 80 ± 0.1 | 15.30 ± 1.1 | 0.78 ± 0.2 |
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Yang, W.; Jiao, L.; Liu, W.; Dai, H. Manufacture of Highly Transparent and Hazy Cellulose Nanofibril Films via Coating TEMPO-Oxidized Wood Fibers. Nanomaterials 2019, 9, 107. https://doi.org/10.3390/nano9010107
AMA Style
Yang W, Jiao L, Liu W, Dai H. Manufacture of Highly Transparent and Hazy Cellulose Nanofibril Films via Coating TEMPO-Oxidized Wood Fibers. Nanomaterials. 2019; 9(1):107. https://doi.org/10.3390/nano9010107
Chicago/Turabian StyleYang, Weisheng, Liang Jiao, Wei Liu, and Hongqi Dai. 2019. "Manufacture of Highly Transparent and Hazy Cellulose Nanofibril Films via Coating TEMPO-Oxidized Wood Fibers" Nanomaterials 9, no. 1: 107. https://doi.org/10.3390/nano9010107
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