Changes in the morphological–mechanical properties and thermal stability of bamboo fibers during the processing of alkaline treatment

Wang, Fang; Zhou, Shujue; Li, Lü; Zhang, Xiaoping

doi:10.1002/pc.24332

Cited by 36 publications

(37 citation statements)

References 46 publications

(52 reference statements)

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“…These are important in fiber fabrication since the fiber has to undergo high temperature and different environment during manufacture process and practical deployment. [23][24][25] In addition, as it has been reported, polymer optical gain materials generally show strong phase separation when blended with the transparent matrix such as PMMA and PS. This phase separation represents poor compatibility between two materials, which can be induced by temperature, magnetic field, processing method, and even film thickness.…”

mentioning

confidence: 80%

Gain Properties and Distributed Feedback Laser Performance of 7F6/Poly(Styrene) Blend Films: Potential Core Material for Plastic Optical Fiber Expanding the Bandwidth to Visible Region

Zhang

et al. 2018

Macro Chemistry & Physics

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Optical gain properties of blue emission oligomer 7‐unit 9,9‐dihexylfluorene (7F6) and its blends with polystyrene (PS) are reported. 7F6 demonstrates high photoluminescence quantum yield (65%), low amplified spontaneous emission threshold (EthASE = 0.6 kW cm−2), high gain coefficient (g = 90.9 cm−1), and extremely low distributed feedback laser threshold (Ethlaser = 86 W cm−2). Unlike polymer gain materials, the phase separation between 7F6 and PS is small even in a high blending ratio. The 70 and 50 wt% 7F6/PS blends display excellent gain properties with g = 70.7 and 64.3 cm−1, EthASE = 1.1 and 2.1 kW cm−2, and Ethlaser = 0.3 and 0.41 kW cm−2, respectively. The photostability and thermal stability are improved significantly by blending 7F6 into PS. These results promise 7F6/PS blends as a potential core material for expanding the bandwidth of plastic optical fiber.

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mentioning

confidence: 80%

Gain Properties and Distributed Feedback Laser Performance of 7F6/Poly(Styrene) Blend Films: Potential Core Material for Plastic Optical Fiber Expanding the Bandwidth to Visible Region

Zhang

et al. 2018

Macro Chemistry & Physics

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“…For instance, the main cause of poor thermal stability in wood is related to the random, branched structures in the hemicelluloses. [13] Photodegradation is mainly due to lignin decomposition on the wood surface from ultraviolet (UV) irradiation. [14,15] Thus, the use of polymers to substitute some of the more problematic components in wood and to develop a new cell wall could be an efficient method of stabilizing wood and thereby overcome some of its aforementioned deficiencies.…”

Section: Introductionmentioning

confidence: 99%

Thermal properties enhancement of poplar wood by substituting poly(furfuryl alcohol) for the matrix

Dong

et al. 2019

Polymer Composites

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Using high‐performance polymers to replace the weak points in wood may be an efficient approach to overcoming certain drawbacks while improving the properties of wood. This study investigated the feasibility of easily replacing part of the wood matrix in poplar wood with renewable poly(furfuryl alcohol) (PFA). The wood was first treated with an alkali solution and was then immersed in a furfuryl alcohol (FA) solution followed by in situ polymerization. After delignification, a large part of hemicelluloses and lignin were removed. In addition, wood porosity increased and more PFA was polymerized in the wood cell walls, resulting in increased weight percent gain and efficient bulking. The thermogravimetric analysis results indicated that the reformation strongly affected the wood thermal stability. A transformation with 30% FA maintained the porous structure of the wood and resulted in the highest maximum degradation temperature. The dynamic mechanical analysis results also indicated that reformation allowed for greater stress transfer at the interface and resulted in a lower damping peak and a higher storage modulus. Our approach, therefore, could provide a promising method to enhance the performance of wood by reforming the wood components and structures.

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“…Furthermore, there were several researches on the structure and mechanical properties of bamboo strips and dusts [7,8], bamboo fiber bundles [9,22] and bamboo pulp [23]. Chemical composition, a lattice transformation from cellulose I to cellulose II, and mechanical properties of bamboo fibers changed differently according to the concentration of alkali treatment.…”

Section: Introductionmentioning

confidence: 99%

Effect of alkali treatment on wettability and thermal stability of individual bamboo fibers

et al. 2018

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The aim of this study is to examine the wettability and thermal properties of individual bamboo fibers after alkali treatment. The individual bamboo fibers were treated by sodium hydroxide (NaOH) solution with varying concentrations (6, 8, 10, 15 and 25%) followed by freeze-drying treatment. The surface analysis of alkali-treated individual bamboo fibers was characterized by atomic force microscope. Water droplet on the individual fiber surface was observed with drop shaper analyzer and the contact angles on fiber surface were also measured. Thermal properties were further studied by thermogravimetric analysis. The results indicated that alkali treatment resulted in the increase in surface roughness of individual bamboo fibers. Alkali treatment with low NaOH concentration could enhance the wettability of treated individual bamboo fibers, and while the wettability was reduced with alkali treatment at high concentration (25%). Thermal analysis revealed that the onset of decomposition and the maximum decomposition were moved to higher temperature after alkali treatment at low NaOH concentrations (6, 8, and 10%), suggesting the improvement in the thermal stability of treated individual bamboo fibers, while the thermal stability was compromised after alkali treatment at higher concentrations (15 and 25%).

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Changes in the morphological–mechanical properties and thermal stability of bamboo fibers during the processing of alkaline treatment

Cited by 36 publications

References 46 publications

Gain Properties and Distributed Feedback Laser Performance of 7F6/Poly(Styrene) Blend Films: Potential Core Material for Plastic Optical Fiber Expanding the Bandwidth to Visible Region

Gain Properties and Distributed Feedback Laser Performance of 7F6/Poly(Styrene) Blend Films: Potential Core Material for Plastic Optical Fiber Expanding the Bandwidth to Visible Region

Thermal properties enhancement of poplar wood by substituting poly(furfuryl alcohol) for the matrix

Effect of alkali treatment on wettability and thermal stability of individual bamboo fibers

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