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1. Moisture- and freeze-thaw-induced deterioration of natural fiber composites with low fiber contents

   https://doi.org/10.26168/icbbm2019.57  

   Noonan, K. ( June 2019 , Academic journal of civil engireering)

   Social, political, and environmental pressures continue to drive the development of sustainable alternatives to petroleum-based materials. Accordingly, natural fiber composites (NFCs) are being developed and used for a range of low- and high- performance applications, such as packaging, automotive parts, and construction materials. As the use of NFCs become more widespread, there is a rising need to investigate the effect of weathering on this emerging class of materials. Previous studies on the moisture and freeze-thaw induced deterioration of NFCs have focused primarily on composites with high fiber contents (>50% by volume). Due to factors, such as low cost, bio-renewability, and enhanced mechanical properties, most commercially available NFCs maximize the content of natural fibers. However, high fiber contents also increase susceptibility to the deleterious effects of environmental aggressors (e.g., moisture and temperature). Since limited data exists on the durability of low-fiber content NFCs, this study investigates the moisture-induced deterioration of NFCs with low fiber content and explicitly analyzes the added effects due to freezing and thawing. Results from a combination of environmental conditioning and X-ray tomography provide and visual evidence of the effect of moisture-induced damage in low-fiber NFCs. Results also show that this deterioration is exacerbated by below-freezing temperatures. Investigating the response of NFCs to such environmental aggressors as demonstrated in this study provides an evidenced-based approach for material design, which ultimately depends on both the intended application and expected environmental conditions. 

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2. Analyzing the Mechanical Properties of Thermoplastic Reinforced with Natural Fibers

   Nidhi M Thanki, Abigail Henderson ( January 2021 , ACS)

   ACS (Ed.)

   Synthetic fibers such as glass, carbon, etc., are used as reinforcement in polymer composites due to their high strength and modulus. However, synthetic fibers contribute to high costs and have a significant environmental impact. To overcome this challenge, various natural fibers, including banana, kenaf, coir, bamboo, hemp, and sisal fiber, as reinforced in a polymer matrix are investigated for mechanical properties. In this study, biocomposites with natural fibers as reinforced are developed and characterized. Treated and untreated natural fibers such as flax, maple, and pine as reinforced in thermoplastic, in this study, polypropylene (PP), are investigated for the mechanical properties, including tensile, flexural, and impact test. Mechanical test results exhibited that adding the natural fibers enhanced the tensile, flexural, and impact properties. It can be inferred that these biocomposites can be used as potential materials for the automobile industry. 

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3. Hybrid hemp/glass fiber reinforced high-temperature shape memory photopolymer with mechanical and flame-retardant analysis

   https://doi.org/10.1038/s41598-023-44710-6  

   Mahmud, Sakil ; Konlan, John ; Deicaza, Jenny ; Li, Guoqiang ( October 2023 , Scientific Reports)

   Cultivated natural fibers have a huge possibility for green and sustainable reinforcement for polymers, but their limited load-bearing ability and flammability prevent them from wide applications in composites. According to the beam theory, normal stress is the maximum at the outermost layers but zero at the mid-plane under bending (with (non)linear strain distribution). Shear stress is the maximum at the mid-plane but manageable for most polymers. Accordingly, a laminated composite made of hybrid fiber-reinforced shape memory photopolymer was developed, incorporating strong synthetic glass fibers over a weak core of natural hemp fibers. Even with a significant proportion of natural hemp fibers, the mechanical properties of the hybrid composites were close to those reinforced solely with glass fibers. The composites exhibited good shape memory properties, with at least 52% shape fixity ratio and 71% shape recovery ratio, and 24 MPa recovery stress. After 40 s burning, a hybrid composite still maintained 83.53% of its load carrying capacity. Therefore, in addition to largely maintaining the load carrying capacity through the hybrid reinforcement design, the use of shape memory photopolymer endowed a couple of new functionalities to the composites: the plastically deformed laminated composite beam can largely return to its original shape due to the shape memory effect of the polymer matrix, and the flame retardancy of the polymer matrix makes the flammable hemp fiber survive the fire hazard. The findings of this study present exciting prospects for utilizing low-strength and flammable natural fibers in multifunctional load-bearing composites that possess both flame retardancy and shape memory properties.

    

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4. Low‐temperature compounding of flax fibers with polyamide 6 via solid‐state shear pulverization: Towards viable natural fiber composites with engineering thermoplastics

   https://doi.org/10.1002/pc.25184  

   Wakabayashi, Katsuyuki ; Vancoillie, Simon H. E. ; Assfaw, Mekdes G. ; Choi, David H. ; Desplentere, Frederik ; Van Vuure, Aart W. ( December 2018 , Polymer Composites)

   Low‐temperature compounding of natural fiber/thermoplastic composites via solid‐state shear pulverization (SSSP) is explored for the first time, with a goal of processing temperature‐sensitive natural fibers with high temperature‐melting engineering thermoplastics without fiber degradation. The model study was based on polyamide 6 (PA6) as the matrix material and short flax fibers as the filler materials; flax fiber type was varied to provide a range of comparison. Composite structural characterization was conducted using computer tomography, optical microscopy, and scanning electron microscopy, while mechanical property measurements were performed on injection molded specimens in both tension and bending. SSSP demonstrated robust and effective processing results in model PA6/flax composites, especially when compared with conventional extrusion. SSSP was able to isolate unmodified scutched fibers into individual elementary fibers with minimal scission, and effectively distribute them in the polymer matrixin situ. The dispersed and distributed filler morphology led to mechanical property enhancements, including 230% and 40% increases in Young's modulus and tensile strength, respectively, compared with neat PA6, at a 20 vol% fiber content. POLYM. COMPOS., 40:3285–3295, 2019. © 2018 Society of Plastics Engineers

    

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5. Effects of Silk Humidity Exposure on Silk/Resin Affinity for Silk Reinforced Composites

   https://doi.org/10.5281/zenodo.580785  

   Ava L. Robson, Lauren D. ( July 2021 , American journal of advanced research)

   Thanks to its comparable specific mechanical properties to glass fibers, silk is a natural fiber that can be used as an eco-friendly alternative to synthetic reinforcing fibers in composite materials. Compared to natural fibers, especially plant fibers, silk enjoys higher mechanical performances, lower density, and higher elongation even at low temperatures, silk also exhibits other attractive qualities like flame resistance and being naturally continuous. However, silk is known to be prone to moisture absorption from surrounding humid environments. Moisture absorption may alter the silk/resin dynamics during composite manufacturing, and later lead to prem-ature degradation in the composite thermomechanical properties. This study investigates the effect of humidity on silk/resin wettability using two different resins (one epoxy and one vinyl ester) and three different silk architectures. Silk fibers are first exposed to different relative humidity environments. Subsequently, the affinity of the conditioned silk to a set of resins is assessed through measurements of silk/resin contact angle over time. Different silk/resin systems were observed to have contrasting responses to humidity exposure. While some silk/resin systems, such as Ahimsa/epoxy, did not show any change after humidity exposure. Other combinations showed tremendous susceptibility of silk/resin affinity to prior exposure of silk to humidity. For instance, although starting at virtually the same initial hydrophobic contact angle of ~123 degrees, Habotai silk/epoxy samples had contrasting wetting times. While the dried Habotai silk reached full wetting after around 5 minutes, the silk samples exposed to humidity took around 1 hour to reach full im-pregnation. These findings demonstrate the importance of humidity exposure control in silk reinforced composites. Keywords: Natural-Fiber Composites, Contact Angle, Silk, Wettability, Humidity. 

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