Your search keyword '"PLANT fibers"' showing total 10,018 results

151. EVALUATION OF MECHANICAL AND MORPHOLOGICAL PROPERTIES COMPOSITE OF AGEL LEAF FIBER (ALF)- EPOXY MODIFIED WITH CARBON POWDER.

Author

Sulistyo, Aris Budi, Wirawan, Willy Artha, and Muslimin, Mukhlis

Subjects

*COMPOSITE materials, *PLANT fibers, *FLEXURAL strength, *HARDNESS testing, *SCANNING electron microscopy

Abstract

This research focuses on the successful development of Agel Leaf Fiber (ALF)-Epoxy composites added with Carbon Active Powder (CAP) and printed using the Vacuum Pressure Infusion (VAPRI) method. Considering the importance of determining the mechanical properties of composites as raw materials for making fishing boats, this research aims to determine the use of Agel Leaf Fiber (ALF) in polymer matrix composites. The composite morphology was analyzed using Scanning Electron Microscopy (SEM) and ImageJ software. The mechanical properties evaluated included Tensile Strength, Flexural Strength, and Hardness. The composite was prepared by incorporating CAP in varying volumes of 0 %, 10 %, and 30 % with a fixed ALF percentage of 40 %. The results showed that the addition of CAP significantly increased the tensile strength to 128.51 MPa, with 0.068 % elongation, 1787.39 MPa modulus of elasticity, and a hardness value of 75.2 HD. Furthermore, the addition of 10 % carbon exhibited a remarkable improvement in flexural strength, reaching 238.51 MPa. This improvement could be attributed to reduced porosity, resulting in enhanced bonding between ALF-CAP-Epoxy components. The flexural strength of the composite with the highest CAP content experienced a significant increase of 238.51 MPa. Thus, Agel leaf fiber has the potential to be used as a reinforcing material in the manufacture of composites and is applied in the manufacture of environmentally friendly fishing boat bodies. [ABSTRACT FROM AUTHOR]

Published

2024

152. INVESTIGATION AND ANALYSIS OF NEW FIBER FROM ALLIUM FISTULOSUM L. (SCALLION) PLANT'S TASSEL AND ITS SUITABILITY FOR FIBER-REINFORCED COMPOSITES.

Author

Eryılmaz, Oğuz and Ovalı, Sabih

Subjects

*ALLIUM fistulosum, *FIBROUS composites, *PLANT fibers, *TENSILE tests, *NATURAL fibers

Abstract

Eco-friendly materials receive more attention due to the necessity of addressing pollution and resource depletion in the face of exponential industrial expansion. Natural fibers provide a sustainable substitution, especially in green composites. This study investigated the feasibility of Allium fistulosum L. (Scallion) as a fiber resource for composite applications by using its tassel. Allium fistulosum L. is derived from a widely available plant and its waste tassels of the plant provide fiber properties and have the potential to be a reinforcing component in composites. The investigation involves characterizing Allium fistulosum L. (AfL) fibers through various analyses. The density of the AfL was determined approximately 1.35 - 1.45 g/cm3. The percentages of lignin, hemicellulose, and cellulose were found to be 24.31%, 29.73%, and 38.36%, respectively. FTIR and XRD analysis affirm AfL's cellulose, hemicellulose, and lignin presence. SEM images indicate a rough surface, necessitating modification for better matrix compatibility. TGA shows suitable thermal stability, majorly degrading beyond 267°C. Tensile testing demonstrates a tensile strength of 22.19 ±3.75 MPa and 0.87 ±0.16 GPa modulus, exceeding some natural fibers like aerial banyan tree roots and Cordia dichotoma. Results show promising features, indicating the viability of AfL fibers in composites with reduced environmental impact and economic benefits. [ABSTRACT FROM AUTHOR]

Published

2024

153. DOE coupled MLP-ANN for optimization of thrust force and torque during drilling of CCFRP composite laminates.

Author

Shetty, Sawan, Shetty, Raviraj, Nayak, Rajesh, Hegde, Adithya, Shetty S. V., Uday Kumar, and Sudheer M.

Subjects

*ARTIFICIAL neural networks, *RESPONSE surfaces (Statistics), *LAMINATED materials, *FIBER-reinforced plastics, *PLANT fibers

Abstract

Advancements in technology and the compulsion to use environment-friendly materials have been challenging tasks for researchers for the past two decades. Researchers have been focusing on the utilization of plant fibers to produce good quality fiber-reinforced polymer/polyester composites for automobile, structural, and building applications. Researchers have been looking for high-quality and cost-effective drilling processes. The primary goal of this study is to identify optimal drilling conditions for CCFRP composite laminates, affecting thrust force and torque. This is achieved by manipulating drilling process variables using Taguchi's Design of Experiments (TDOE), Analysis of variance (ANOVA), Response Surface Methodology (RSM), Desirability Function Analysis (DFA) and Artificial Neural Network (ANN). From the results, it was observed that the spindle speed of 2000 rpm, feed of 15 mm/min, point angle of 90°, fiber length of 6 mm, fiber volume of 30%, and fiber diameter of 7 microns gave the optimum results for obtaining minimum thrust force and torque. Further RSM revealed that an increase in fiber vol % and a decrease in spindle speed resulted in an increase in thrust force and torque. From DFA optimization results, the minimum thrust force of 24.0042N and minimum torque of 0.8001N-m was obtained. Finally, the experimental values of thrust force and torque were compared with the corresponding values predicted by the MLP-ANN model. The average error percentage for thrust force and torque was 1.75% and 6.56% respectively. [ABSTRACT FROM AUTHOR]

Published

2024

154. Contribution of micropores in porous zirconia spheres to high optical transparency of dental resin composites.

Author

Shingo MIZOBUCHI, Masataka OHTANI, and Kazuya KOBIRO

Subjects

DENTAL resins, DENTAL materials, SPHERES, MICROPORES, ZIRCONIUM oxide, PLANT fibers

Abstract

Transparency to UV-Vis light and radiopacity of dental resin composites containing zirconia (ZrO2) fillers were investigated. The transparency of the resin composite containing porous ZrO2 spheres was much higher than that containing irregularly shaped ZrO2 particles. Calcination of the porous ZrO2 spheres at high temperatures led to dramatically reduced specific surface areas and pore volumes. The transparency of the resin composite containing the calcined porous ZrO2 spheres drastically decreased as the calcination temperature increased. Then, the enhanced UV-Vis transmittance of the resin composite containing porous ZrO2 spheres is attributed to the concentration and physical characteristics of the pores. The radiopacity of the resin composites containing porous ZrO2 spheres increased slightly with increasing calcination temperature. This study revealed that the internal structure of the ZrO2 fillers mainly influenced in the UV-Vis light transmittance of the resin composites. [ABSTRACT FROM AUTHOR]

Published

2024

155. NEW MATERIALS FOR ENHANCING THE DURABILITY OF MURAL PAINTINGS OF THE TOMB OF QEN-AMUN TT 93, LUXOR, EGYPT.

Author

Orabi, E. and Sallam, A.

Subjects

MURAL art, PLANT fibers, ETHYL silicate, FOURIER transform infrared spectroscopy, CLAY minerals, TOMBS

Abstract

The aim of this research is to study the main deterioration aspects and evaluate the treatment of mural painting at the Tomb of Qen-Amun TT93 dating back to the 18th dynasty, New Kingdom (c. 1550-1069 BC.), in the Theban Necropolis, on the west bank of the Nile in Luxor. In this study, the surface of deteriorated mural paintings were investigated using PLM, TEM investigation of the eggshell nanoparticles, XRD analysis, FTIR spectroscopy, and SEM-EDX. To our knowledge, it is the first report on the mixture of the ethyl silicate and the egg shell nanoparticles application of mixture for the treatment of deteriorated mural painting surfaces in the Tomb of Qen-Amun TT93. The samples were collected from the fragment of wall painting, painted with the depiction of two women, Tomb of Qen-Amun (TT93). The obtained results showed that the structures fragment of wall painting included three layers from the top to bottom: yellow pigment, fine plaster, coarse plaster composed of quartz, clay minerals, iron oxides, and plant fibers. The results illustrated that the mixture was highly effective at consolidating cracks, and the appearance of the treated surfaces was. [ABSTRACT FROM AUTHOR]

Published

2024

156. Insights into the interfacial transfer impedance behavior of moisture and dynamics of sorption diffusion in dried tobacco leaves surface.

Author

Ma, Haowei, Jiang, Zhiqin, Tie, Jinxin, Cheng, Changhe, Wu, Jian, Zhong, Yongjian, Gao, Feng, Zhan, Xiaoli, and Zhang, Qinghua

Subjects

SORPTION, PLANT fibers, POROSITY, PAPER industry, DIFFUSION, MOISTURE, CIGARETTES

Abstract

Moisture sorption and diffusion processes of plant fiber materials have a significant impact on their properties and product quality in healthcare, food production, cigarette processing, textile field, and papermaking industry. The infiltration process affects the rate of water sorption and processing of flavoring liquids, and exploring its mechanisms can optimize the production process. Here, multi-scale imaging approach was employed to identify the heterogeneous structure of plant leaves and the impact of multilevel fiber structure and pore channels on water adsorption. The dissipative changes and mechanisms of water adsorption, osmotic diffusion, and hygroscopic swelling in plant leaves were illustrated. Furthermore, the effects of temperature and water activity on water diffusion under different environmental conditions are determined through a comparison of adsorption equilibrium and diffusion electrochemical impedance analysis (EIS), with a focus on the water-blocking effect of the waxy layer interface. This work investigated the correlation between the impedance change in water transport and the natural layered water-blocking polymer film structure and multi-level pore structure. This study sheds new light on biological multi-scale fiber materials and these findings are important reference value for manufacturing processes to improve the moisturizing properties of functional plant fibers in the field of food preservation. [ABSTRACT FROM AUTHOR]

Published

2024

157. Cellulose based hierarchically structured anion-exchange fiber for efficient dye adsorption.

Author

Shao, Xinyi, Wang, Jian, Yao, Xinjie, Wang, Yubo, Song, Wenbao, Xu, Dehua, Gao, Yifei, and Dong, Cuihua

Subjects

CELLULOSE fibers, DYES & dyeing, CELLULOSE, VAN der Waals forces, HOLLOW fibers, PLANT fibers, NATURAL fibers

Abstract

Ion-exchange fiber has been widely used as a conventional adsorbent for water purification, but its base material, the petroleum, does not comply with the current trend of environmental protection. The synthesis of functional materials from natural resources attracts intensive interest. Cotton lint fiber is a natural cellulose based hollow fiber, which has a unique advantage in ion-exchange process. Herein, for the first time, a cationic design for the cotton lint fiber was carried out in a simple two-step strategy. The cellulose based anion-exchange fiber (CAF) showed well-preserved fibrous macrostructure and cellulose nanofibril structure. And the ideal cationic group content (133.26 mmol·100 g−1) of it indicates the successful combination of structural and functional properties, which are the responsible for its excellent adsorption efficiency that includes the high adsorption capacity (above 1300 mg g−1), rapid adsorption rate (90% of its equilibrium uptake within 6 min at the initial concentration of 300 mg L−1), perfect solid/liquid separation property, and good recyclability (> 95%) for congo red. Additionally, the adsorption mechanism can be attributed to the synergistic effect of electrostatic attraction, hydrogen bonding, and van der Waals force, which was explained by the employment of classical adsorption models and advanced double layer statistical physical model. The results show that this functionalized biomaterial is an ideal candidate to replace the conventional anion-exchange fiber. This work not only revolutionizes the application of natural plant fiber, but also provides a cost-effective and simple strategy for the utilization of cellulose. [ABSTRACT FROM AUTHOR]

Published

2024

158. Preparation and characterization of snake plant fiber reinforced composite: A sustainable utilization of biowaste.

Author

Mishfa, Kaniz Fatima, Alim, Md. Abdul, Repon, Md. Reazuddin, Habibullah, MD, Tonmoy, Mohd Abir Hossen, Jurkonienė, Sigita, and Shukhratov, Sharof

Subjects

PLANT fibers, FIBROUS composites, NATURAL fibers, FOURIER transform infrared spectroscopy, EPOXY resins, FIBER-reinforced plastics, PLANT polymers, POLYACRYLONITRILES

Abstract

Natural fibers are one of the most attractive materials in biocomposites due to their potential for sustainability. This study aims to prepare sustainable composite materials using fibers from Sansevieria trifasciata (snake plant) and to investigate their mechanical, morphological, and water absorption properties. The composite was prepared with epoxy resin through a manual hand lay‐up process, maintaining standard parameters with changeable reinforcement (10%, 20%, and 30%). The mechanical properties (tensile, impact, and flexural strength), Scanning Electron Microscopy (SEM), Fourier Transform Infrared Spectroscopy (FTIR), and water absorbency of the composites were evaluated. The result showed that the tensile strength, flexural strength, and impact resistance of the composites are 6.99 MPa, 10.77 MPa, and 14 J, respectively, for 30% fiber components, which are significantly higher than other composite materials. The SEM analysis showed a strong interfacial bond between the snake plant fiber and the epoxy resin. The FTIR analysis revealed a reduction in hemicellulose and lignin and an improvement in the interfacial adhesion between snake plant fiber and epoxy resin. The composites also demonstrated time‐dependent increases in water absorption, with the sample containing 30% fiber components showing the best absorbency performance at 0.88%. Highlights: A study is being conducted on the effective and sustainable use of biowaste.The composite materials loaded with 30% fibers had significantly high tensile strength, flexural strength, and impact resistance.The SEM analysis of snake plant fiber‐reinforced polymer composite showed a strong interfacial bond between fiber and epoxy resin.The FTIR analysis of the composite revealed the reduction of hemicellulose and lignin.The use of non‐renewable materials is reduced, and eco‐friendliness is promoted. [ABSTRACT FROM AUTHOR]

Published

2024

159. LAS INICIATIVAS DE COOPERACIÓN ARTESANAL DEL COLEGIO DE TINTOREROS DE SEDA DE VALENCIA Y LA POLÍTICA DE MEJORA DEL TINTE EN LA SEGUNDA MITAD DEL SIGLO XVIII.

Author

FRANCH BENAVENT, Ricardo

Subjects

SILK dyeing, TEXTILE fibers, PLANT fibers, MONARCHY, DYERS

Abstract

Copyright of Studia Histórica: Historia Moderna is the property of Ediciones Universidad de Salamanca and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

160. Raman Spectra of Delignified Plant Fibers: Exploring the Impact of Xylan's Presence on the Spectral Features of Cellulose.

Author

Agarwal, Umesh P. and Ralph, Sally A.

Subjects

PLANT fibers, RAMAN spectroscopy, XYLANS, CELLULOSE, HEMICELLULOSE, WOOD

Abstract

Wood and plants are made of fibers that contain, in addition to cellulose, lignin and hemicelluloses. Xylan and galactoglucomannan are the dominant secondary cell wall hemicelluloses. In modern times, fibers are important materials for the biorefinery industry and for developing biocomposites. For these and other applications, the structural analysis of fibers is important, and Raman spectroscopy is among the many analytical techniques used. However, given the structural similarity between hemicelluloses and cellulose, many of their Raman contributions overlap, and the extent to which the overlapping features of hemicellulose modify the spectrum of cellulose is not yet fully understood. The present investigation focuses on this aspect by examining xylan, one of the hemicelluloses. As a model system, samples with various mass ratios of cotton microcrystalline cellulose (MCC) and xylan (birch wood) were prepared and analyzed using FT-Raman spectroscopy. In most cases, the Raman intensities were sample-composition-dependent, and, when the selected band intensities were plotted against the xylan content, good linear correlations (with an R2 between 0.69 and 1.0) were obtained. The results indicated that with increased xylan content, the peak intensities increased at 1460, 898, and 494 cm−1 and declined at 1480, 1121, 1096, and 520 cm−1. Additionally, intensity changes (%) in the MCC bands with respect to MCC's fractions in various mixture samples showed that, in most cases, the mixture intensities increased and were highly correlated with the xylan amounts in the mixtures (with an R2 between 0.75 and 0.97). These findings were applied to interpret Raman spectra of selected xylan-containing delignified plant fibers. It is hoped that the insights gained in this study will allow for better interpretation of the spectra of natural and treated plant materials. [ABSTRACT FROM AUTHOR]

Published

2024

161. BEHAVIOR OF CEMENT MORTAR WITH THE ADDITION OF COCONUT FIBERS.

Author

Ponse Santos, Andressa, Pereira do Nascimento, Matheus Rodrigues, Souza Barboza, Christian, and Ramos Omido, Agleison

Subjects

CEMENT composites, PLANT fibers, NATURAL fibers, POLYMERIC composites, CEMENT, COMPOSITE materials, LITERATURE reviews, BEHAVIORAL assessment, CEMENT coating, MORTAR

Abstract

Copyright of Environmental & Social Management Journal / Revista de Gestão Social e Ambiental is the property of Environmental & Social Management Journal and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

162. Rhamnogalacturonan I with β-(1,4)-Galactan Side Chains as an Ever-Present Component of Tertiary Cell Wall of Plant Fibers.

Author

Chernova, Tatyana, Mikshina, Polina, Petrova, Anna, Ibragimova, Nadezhda, Ageeva, Marina, and Gorshkova, Tatyana

Subjects

*PLANT fibers, *PLANT cell walls, *CELL anatomy, *NUCLEAR magnetic resonance, *LIGHT scattering, *CHLORELLA vulgaris

Abstract

The cellulose-enriched tertiary cell walls present in many plant fibers have specific composition, architecture, machinery of formation, and function. To better understand the mechanisms underlying their mode of action and to reveal the peculiarities of fibers from different plant species, it is necessary to more deeply characterize the major components. Next to overwhelming cellulose, rhamnogalacturonan I (RG-I) is considered to be the key polymer of the tertiary cell wall; however, it has been isolated and biochemically characterized in very few plant species. Here, we add RG-I to the list from the phloem fibers of the Phaseolus vulgaris stem that was isolated and analyzed by nuclear magnetic resonance (NMR), dynamic light scattering, and immunolabeling, both within tissue and as an isolated polymer. Additionally, fibers with tertiary cell walls from nine species of dicotyledonous plants from the orders Malphigiales, Fabales, and Rosales were labeled with RG-I-related antibodies to check the presence of the polymer and compare the in situ presentation of its backbone and side chains. The obtained results confirm that RG-I is an obligatory polymer of the tertiary cell wall. However, there are differences in the structure of this polymer from various plant sources, and these peculiarities may be taxonomically related. [ABSTRACT FROM AUTHOR]

Published

2023

163. Genomic and Cytogenetic Analysis of Synthetic Polyploids between Diploid and Tetraploid Cotton (Gossypium) Species.

Author

Khidirov, Mukhammad T., Ernazarova, Dilrabo K., Rafieva, Feruza U., Ernazarova, Ziraatkhan A., Toshpulatov, Abdulqahhor Kh., Umarov, Ramziddin F., Kholova, Madina D., Oripova, Barno B., Kudratova, Mukhlisa K., Gapparov, Bunyod M., Khidirova, Maftunakhan M., Komilov, Doniyor J., Turaev, Ozod S., Udall, Joshua A., Yu, John Z., and Kushanov, Fakhriddin N.

Subjects

POLYPLOIDY, GENOMICS, COTTON, PLANT fibers, COTTON fibers, POLLEN viability, SPECIES

Abstract

Cotton (Gossypium spp.) is the most important natural fiber source in the world. The genetic potential of cotton can be successfully and efficiently exploited by identifying and solving the complex fundamental problems of systematics, evolution, and phylogeny, based on interspecific hybridization of cotton. This study describes the results of interspecific hybridization of G. herbaceum L. (A1-genome) and G. mustelinum Miers ex Watt (AD4-genome) species, obtaining fertile hybrids through synthetic polyploidization of otherwise sterile triploid forms with colchicine (C22H25NO6) treatment. The fertile F1C hybrids were produced from five different cross combinations: (1) G. herbaceum subsp. frutescens × G. mustelinum; (2) G. herbaceum subsp. pseudoarboreum × G. mustelinum; (3) G. herbaceum subsp. pseudoarboreum f. harga × G. mustelinum; (4) G. herbaceum subsp. africanum × G. mustelinum; (5) G. herbaceum subsp. euherbaceum (variety A-833) × G. mustelinum. Cytogenetic analysis discovered normal conjugation of bivalent chromosomes in addition to univalent, open, and closed ring-shaped quadrivalent chromosomes at the stage of metaphase I in the F1C and F2C hybrids. The setting of hybrid bolls obtained as a result of these crosses ranged from 13.8–92.2%, the fertility of seeds in hybrid bolls from 9.7–16.3%, and the pollen viability rates from 36.6–63.8%. Two transgressive plants with long fiber of 35.1–37.0 mm and one plant with extra-long fiber of 39.1–41.0 mm were identified in the F2C progeny of G. herbaceum subsp. frutescens × G. mustelinum cross. Phylogenetic analysis with 72 SSR markers that detect genomic changes showed that tetraploid hybrids derived from the G. herbaceum × G. mustelinum were closer to the species G. mustelinum. The G. herbaceum subsp. frutescens was closer to the cultivated form, and its subsp. africanum was closer to the wild form. New knowledge of the interspecific hybridization and synthetic polyploidization was developed for understanding the genetic mechanisms of the evolution of tetraploid cotton during speciation. The synthetic polyploids of cotton obtained in this study would provide beneficial genes for developing new cotton varieties of the G. hirsutum species, with high-quality cotton fiber and strong tolerance to biotic or abiotic stress. In particular, the introduction of these polyploids to conventional and molecular breeding can serve as a bridge of transferring valuable genes related to high-quality fiber and stress tolerance from different cotton species to the new cultivars. [ABSTRACT FROM AUTHOR]

Published

2023

164. Effects of Chitosan on the Characteristics of Sorbitol Plasticised Cellulose Acetate/Starch Bioplastics.

Author

Rahmatullah, Putri, Rizka Wulandari, Nurisman, Enggal, Susmanto, Prahady, Haryati, Sri, Waristian, Harry, Zulkifli, Muzafar, Minata, Tree Silvia Putri, and Meidina, Shenia

Subjects

CHITOSAN, CELLULOSE acetate, BIODEGRADABLE plastics, PLANT fibers, ELASTICITY

Abstract

Due to the natural origins of its primary components, such as plant fibers, bioplastics are materials that disintegrate quickly. Typically, plasticizers are used to create cellulose-based bioplastics. Plasticizers soften hard, inflexible structures, improve elasticity and flexibility, and lessen bioplastics' tendency to break. The manufacturing of bioplastics in this study includes the incorporation of chitosan and sorbitol plasticizers as a variable. Chitosan and sorbitol were utilized in the following mass ratios: 0.5 g, 1.0 g, and 20 %, 30 %, and 40 %. The optimal chitosan and sorbitol concentrations produced the most desirable bioplastic properties. At a ratio of 20 % sorbitol and 0.5 g chitosan, the greatest bioplastic value for tensile strength (845.68 kPa) and Young's modulus (67.65 x 102 KPa) was attained. With values of 44.94 % and 81.28 %, respectively, the ratio of 30 % sorbitol to 1 g chitosan produced the best mass and water absorption values. At a ratio of 30 % sorbitol and 0.5 g chitosan at 0.94 g/mL and a ratio of 40 % sorbitol and 1 g chitosan at 1.75 %, the highest density and elongation values were identified. [ABSTRACT FROM AUTHOR]

Published

2023

165. Novel okra woven fabric reinforced polylactic acid composites: Mechanical, morphological, and thermal properties.

Author

Rahman, A. N. M. Masudur, Zhang, Xueping, Qin, Xiaohong, Sayeed, M. M. Alamgir, and Islam, Syed Rashedul

Subjects

*POLYLACTIC acid, *OKRA, *THERMAL properties, *PLANT fibers, *WOVEN composites, *SCANNING electron microscopy

Abstract

Contemporary researchers are directing attention towards enhancing the structural integrity of biodegradable matrices, such as polylactic acid (PLA), through the incorporation of plant fibers. The utilization of novel fibers is becoming more prevalent to achieve the specific demands of composite applications, particularly in the automotive and packaging fields. Woven fabrics are commonly favored for reinforcing composites due to their elevated specific strength and dimensional stability. In pursuit of this context, we have developed a unique woven fabric using 100% okra fiber and utilized it in the production of PLA biocomposites. This approach was made due to the unexplored potential of okra woven fabric in the field of composite manufacturing. To optimize the performance of the composites, three distinct weight proportions of okra woven fabric (OWF) were chosen, including 20%, 30%, and 40%. The obtained composites were mechanically, morphologically, and thermally characterized. The manufactured composite's maximum tensile and thermal property was attained by adding 20% OWF to the PLA. Scanning electron microscopy analysis revealed that 20% OWF composite possessed superior fiber‐matrix adhesion, improving all properties' efficacy. The overall findings reveal that the OWF/PLA composites are promising as a green material for applications in the automotive and packaging industries. Highlights: A novel class of composite has been created using 100% okra woven fabric.The composite with 20% fabric content showed the best mechanical properties.Thermal properties of composites are also optimized using 20% fabric content.SEM confirms the strong fiber‐matrix bonding of 20% OWF/PLA composites.The composites are suitable for automotive and packaging applications. [ABSTRACT FROM AUTHOR]

Published

2023

166. Hub Genes in Stable QTLs Orchestrate the Accumulation of Cottonseed Oil in Upland Cotton via Catalyzing Key Steps of Lipid-Related Pathways.

Author

Alam, Beena, Liu, Ruixian, Gong, Juwu, Li, Junwen, Yan, Haoliang, Ge, Qun, Xiao, Xianghui, Pan, Jingtao, Shang, Haihong, Shi, Yuzhen, Yuan, Youlu, and Gong, Wankui

Subjects

*COTTONSEED oil, *COTTON, *VEGETABLE oils, *FOOD supply, *GENES, *PLANT fibers, *LIPIDS

Abstract

Upland cotton is the fifth-largest oil crop in the world, with an average supply of nearly 20% of vegetable oil production. Cottonseed oil is also an ideal alternative raw material to be efficiently converted into biodiesel. However, the improvement in kernel oil content (KOC) of cottonseed has not received sufficient attention from researchers for a long time, due to the fact that the main product of cotton planting is fiber. Previous studies have tagged QTLs and identified individual candidate genes that regulate KOC of cottonseed. The regulatory mechanism of oil metabolism and accumulation of cottonseed are still elusive. In the current study, two high-density genetic maps (HDGMs), which were constructed based on a recombinant inbred line (RIL) population consisting of 231 individuals, were used to identify KOC QTLs. A total of forty-three stable QTLs were detected via these two HDGM strategies. Bioinformatic analysis of all the genes harbored in the marker intervals of the stable QTLs revealed that a total of fifty-one genes were involved in the pathways related to lipid biosynthesis. Functional analysis via coexpression network and RNA-seq revealed that the hub genes in the co-expression network that also catalyze the key steps of fatty acid synthesis, lipid metabolism and oil body formation pathways (ACX4, LACS4, KCR1, and SQD1) could jointly orchestrate oil accumulation in cottonseed. This study will strengthen our understanding of oil metabolism and accumulation in cottonseed and contribute to KOC improvement in cottonseed in the future, enhancing the security and stability of worldwide food supply. [ABSTRACT FROM AUTHOR]

Published

2023

167. Incorporation of Different Physical Forms of Fat Replacers in the Production of Low-Fat/ Reduced-Fat Meat Products: Which is More Practical?

Author

Asyrul-Izhar, Abu Bakar, Bakar, Jamilah, Sazili, Awis Qurni, Meng, Goh Yong, and Ismail-Fitry, Mohammad Rashedi

Subjects

*FAT substitutes, *MEAT, *VEGETABLE oils, *PLANT fibers, *DIETARY fiber, *FAT

Abstract

This review details the different approaches to replacing animal fat used in meat products with non-animal fat ingredients based on their physical forms during processing. Six different physical forms to replace the fat are categorized as 1) powder, 2) paste, 3) plant oils, 4) combinations of dietary fiber with plant oils or animal protein/skin, 5) pre-treated fat replacer, and 6) oleogel and emulsion gels. The ingredients, characteristics, processes, mechanisms, advantages, and disadvantages of all the fat replacers are discussed extensively. The oleogel and emulsion gel approach is found to be the most practical by retaining the solid-like properties while possessing a healthier fatty acid profile over other approaches. This approach also can solubilize both hydrophobic and hydrophilic components and also have good thermodynamic stability, thus imitating the animal fat. In addition, the cost of production is kept low while maintaining the nutritional attributes, physicochemical and sensorial properties of meat products. [ABSTRACT FROM AUTHOR]

Published

2023

168. Research on the pottery decorations and manufacturing techniques of the Houtaomuga Phase I culture.

Author

Li, Penghui and Wang, Lixin

Subjects

*POTTERY, *POTTERY techniques, *PLANT fibers, *NEOLITHIC Period

Abstract

The Houtaomuga Phase I culture represents the earliest Neolithic remains found in Northeast China heretofore, thus filling an over 10,000-year gap in early pottery distribution. Pottery decorations and manufacturing techniques from this culture are unique. The pattern application methods seen are stamping, rolling, and incising. The emergence of flat-bottomed pottery and coiling techniques serves as a prelude to the later ceramic tradition of cylindrical jars with flat bottoms. Comb-teeth decorations along with plant fiber temper indicate similarity with pottery remains in Eastern Siberia and the Russian Far East. [ABSTRACT FROM AUTHOR]

Published

2023

169. Helianthus Annuus L. Comparison of The Properties of Fibers Obtained From The Plant By Methods of Decortication and Retting.

Author

Ataman, Nilsu and Şık, Levent

Subjects

COMMON sunflower, RETTING, PLANT fibers, X-ray diffractometers, BIOPOLYMERS

Abstract

A large amount of sunflower production is carried out in our country. The 2,500,000 tons of sunflower stalks that appeared after production pose a problem for our farmer. In order to clean up this environmental problem from the field, sunflower stalks are destroyed by burning to warm up in winter, broken down and mixed into the soil, or burned after harvesting. It is thought that by obtaining qualified, ecological and naturally decomposing sunflower fiber from the stem of the sunflower plant, which is an agricultural waste, it can increase the added value of agricultural products and contribute to the protection of the environment. In this study, the anatomical characteristics of the stem of the sunflower plant were determined, and natural lignocellulosic fibers were obtained from the sunflower stem by retting and decortication methods (fresh stem, dried stem). Various physical, chemical and mechanical properties of these fibers have been measured. For this purpose, FTIR (Fourier Transform Infrared Spectroscopy) analysis, XRD (X-Ray Diffractometer) analysis and SEM (Scanning Electron Microscope) analysis were applied to the fibers obtained by different methods. Thermal analyses were performed by TG-DTA (Thermogravimetric) analysis. In addition, fiber strength, fiber fineness, fiber length and color measurements were made. The chemical content of the obtained fibers (pectin, lignin, cellulose, hemicellulose) was determined. The properties of the fibers were compared using the obtained data. As a result of the study, it has been seen that the characteristic properties of the sunflower fibers obtained by the retting method are better. It has been determined that the elemental, thermal and crystal structures of the fibers obtained by different methods are similar. It was concluded that sunflower fiber will not be spun as a yarn, but can be used as a natural polymeric composite reinforcement material. [ABSTRACT FROM AUTHOR]

Published

2023

170. Long-term water aging effects on the durability of alkali-treated bamboo fiber reinforced composite.

Author

Chakkour, Mouad, Ould Moussa, Mohamed, Khay, Ismail, Balli, Mohamed, and Ben Zineb, Tarak

Subjects

FIBROUS composites, BAMBOO, YOUNG'S modulus, DURABILITY, TENSILE strength, PLANT fibers

Abstract

This paper investigates the degradation mechanisms and mechanical properties of alkali-modified bamboo fiber composites under long-term water aging (up to 120 days) at 25 °C. The main findings show that alkali-treatment reduces the equilibrium moisture content of composites to 12.01 ± 0.04% after a treatment duration of 48 h. At dry conditions, the tensile strength and modulus of composites reach their maximum values of 290 ± 11.2 MPa and 11.5 ± 0.61 GPa for a soaking time of 4 h, then, gradually drop to smaller values, respectively. Beyond 120 aging-days, the tensile strength of 4, 24 and 48 h-modified fiber composites considerably decreases by 66.32 ± 0.33%, 60.99 ± 0.26% and 81.68 ± 0.41%, respectively. Similarly, their Young's modulus falls by 39.72 ± 0.25%, 49.04 ± 0.19% and 41.71 ± 0.37%, respectively. As confirmed by SEM, this significant drop is attributed to the severe microstructural damage of fibers and matrix which is a result of the prominent differential swelling between the internal cell wall layers. However, the findings attractively reveal a slight decline of about 18.15 ± 0.34% and 15.79 ± 0.33% in the tensile strength of raw and 0.5-h-modified fiber composites after 120 aging-days, respectively. Likewise, their Young's modulus decreases by 18.55 ± 0.4% and 14.47 ± 0.28%, respectively. This good aging resistance of the raw and 0.5-h-modified fiber composites suggests that the matrix plasticization, physical expansion of fibers as well as hydrolysis reaction are the main aging mechanisms. [ABSTRACT FROM AUTHOR]

Published

2023

171. Behaviour and design of natural fibre reinforced concrete

Author

Momoh, Emmanuel Owoichoechi, Osofero, Adelaja Israel, and Menshykov, Oleksandr

Subjects

Fiber-reinforced concrete, Plant fibers

Abstract

The need for alternative construction materials that are both economically and environmentally sustainable cannot be overemphasised. Factors such as rising construction cost, high cost of urban land, and lack of affordable housing finance have made it almost impossible for low and average income earners in developing countries to afford decent housing. Conventional construction materials like reinforced concrete are expensive due to importation of reinforcement steel that is unavailable locally. Furthermore, the energy-intensiveness and high carbon footprint resulting from the manufacturing procedures and transportation of steel has necessitated the need for sustainable and affordable alternative construction materials. Hence the aim of this study is to develop a novel, affordable, and sustainable natural reinforcement for concrete from oil palm broom fibres (OPBF), which are the ribs of the leaflets of the oil palm tree (Elaeis guineensis). Until recently, OPBF were considered a waste and sometimes used as cooking fuel in rural areas or at best for making broom bristles due to its perceived stiffness and durability but without any information on its morphology, physical, and mechanical properties. To achieve this aim, an engineering characterisation of the OPBF was carried out which revealed that the fibres were superior to steel in terms of strength/weight ratio. Investigations into the use of the OPBF in concrete either as discrete randomly distributed reinforcement or as main longitudinal reinforcement were then carried out. In order to overcome the durability challenges associated with natural fibres, a treatment study aimed at improving the bond, physical and mechanical properties of OPBF was also carried out. The study revealed that thermal or chemical treatments were most appropriate for OPBF used as discrete randomly distributed fibres in concrete (OPBF-concrete). For its use as longitudinal reinforcement, steel hose clamps were employed to combine the individual fibres into strand units for the reinforcement of concrete beams (OPBF-reinforced concrete). While Response Surface Models were developed to predict the mechanical properties of OPBF-concrete for up to 112 days, Finite Element Modelling was employed for OPBF-reinforced concrete based on the constitutive relationships derived from the experimental investigations. The Finite Element study also investigated the effect of different parameters on the behaviour of the developed OPBF-reinforced concrete. Finally, design guidance and recommendations were made for which ultimate and serviceability limit states are satisfied. The main conclusion is that the developed natural fibre reinforced concrete can be used for affordable and sustainable housing construction across the world, particularly in developing countries.

Published

2022

172. Effects on the compressive strength of cement-stabilized rammed earth blocks with varied content of buffelgrass-based fibers in wet-dry conditions

Author

Federico Pederson, Reuel Florendo, Saleh Ali Khawaja, Kirk Dimond, and Hee-Jeong Kim

Subjects

rammed earth, cement stabilized rammed earth, plant fibers, buffelgrass, fiber reinforced, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

Stabilized rammed earth blocks have been an alternative building material around the world due to their cost efficiency, low embodied energy, and environmental footprints. However, the lower compressive strength and resistance to wearing limits their use in comparison to higher-cost alternatives. The integration of fibers in rammed earth blocks has been a promising technique for enhancing their properties. In this research, the viability of buffelgrass as a reinforcing fiber in stabilized earth blocks was determined. The buffelgrass was incorporated into the mix up to 5% by weight for samples with the increment of 1% for each mix and the durability was determined under wet and dry conditions. In addition, the influence of the buffelgrass on the compressive strength was observed and the optimum content was determined. The morphological characteristics were observed using SEM imaging of the rammed earth and fiber interaction at a fracture surface. The results showed the inclusion of buffelgrass helps the wear resistance of the earth blocks when exposed to wet-dry conditions as well as slightly improving the compressive strength of the material after dry and wet curing.

Published

2024

173. Nach der Verpackung ist vor der Verpackung: Design for Recycling mit hochwertigem Altpapier.

Subjects

PACKAGING recycling, PAPER recycling, WASTE recycling, WASTE paper, RAW materials, PLANT fibers, PACKAGING, TRADEMARKS

Abstract

Copyright of Wochenblatt für Papierfabrikation is the property of dfv Mediengruppe and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

174. Upcycled Foods BREAK New Ground.

Author

Brewster, Elizabeth

Subjects

*NUTRITION, *SNACK foods, *FOOD industry, *FLOUR, *BAKED products, *BREWER'S spent grain, *PLANT fibers, *BANANAS

Abstract

The article focuses on the emerging trend of commercializing food waste through upcycled products to address the global food waste issue and meet consumer demand for sustainability. Topics include the rapid growth of upcycled food and beverage launches, the significant rise in sales of upcycled snacks, and the expansion of upcycled ingredients into categories such as pet food and bakery products.

Published

2024

175. Preparation of cellulose nanofiber from cassava pulp by high-pressure homogenizer.

Author

Jeencham, Rachasit, Le, Hoang Minh, Numpaisal, Piya-On, and Ruksakulpiwat, Yupaporn

Subjects

*HEMICELLULOSE, *CASSAVA, *CELLULOSE, *PLANT fibers, *SCANNING electron microscopes, *ELECTRON emission, *LIGNIN structure

Abstract

There are many methods used nowadays to obtain cellulose nanofiber (CNF) from plant fibers. However, a major drawback of these methods is the %yield of CNF obtained. In this study, the preparation of CNF from cassava pulp (CP) with the application of a high-pressure homogenizer was explored. CP was treated with sodium hydroxide and then bleached by sodium chlorite/acetate buffer solution. Then a high-pressure homogenizer was used to obtain CNF. The effect of homogenization pressure and the number of cycles on the structure and properties of CNF were investigated. From emission scanning electron microscope (FE-SEM) images, the diameters of CNF decreased with increasing homogenization pressure and the number of cycles, these fibrils were split off into smaller fiber bundles. At optimal preparation conditions, CP with treatment of alkali, bleaching and homogenizing at 25,000 psi and 15 cycles showed diameters in the range of 15-37 nm and estimated lengths of 500-5000 nm, which met the size of the CNF requirement. Fourier transform infrared (FTIR) spectroscopy of all CNF demonstrated that the alkali and bleaching treatments partially removed hemicelluloses and lignin from the structure of fibers leading to higher purity of cellulose. X-ray diffraction (XRD) results were revealed that alkali and bleaching treatments also improved the crystallinity of fibers from 19% in CP to 46% in CNF. Furthermore, FTIR spectroscopy and XRD curves of all CNF showed no significant difference, indicating that the chemical compositions and crystallinity of CNF were not affected by increasing pressure and the number of cycles of the homogenizer. Especially, the preparation of CNF from CP using a high-pressure homogenizer gave a 14.72 % yield. In conclusion, the development of novel CNF from CP can be achieved by an application of the homogenization process. [ABSTRACT FROM AUTHOR]

Published

2023

176. Valuation of a thermal insulation made of cardboard reinforced with alfa plant fibers.

Author

Mellaikhafi, Abdellah, Tilioua, Amine, and Benallel, Abderrahim

Subjects

*PLANT fibers, *LIFE cycle costing, *THERMAL insulation, *HOUSE insulation, *FIBROUS composites, *INSULATING materials

Abstract

This work is part of the valorization of plants available in abundance in the region of Drâa-Tafilalet as the fibers extracted from Alfa plant, respecting the conditions of harvesting to ensure its good regeneration. These fibers present an interesting cellular porous structure, allowing to obtained good thermal insulation properties. The elaboration and experimental characterization of these composite materials based on different weight contents of Alfa fibers (80, 70, 60, 50 and 40%) have been carried out. The thermo-physical properties of five cardboard composites reinforced with the fibers of the Alfa plant were experimentally evaluated using the high insulation house method. In addition, a life cycle cost analysis has been performed to determine the optimal insulation thickness and energy savings. The results of this study show that these insulation materials based Alfa fibers have good thermal properties for the insulation and present several environmental and economic advantages. [ABSTRACT FROM AUTHOR]

Published

2023

177. Thermal and acoustic characterization of thermal insulation materials based on local plant fibers.

Author

Benallel, Abderrahim, Tilioua, Amine, Mellaikhafia, Abdellah, Garoum, Mohammed, and Hamdi, Moulay Ahmed Alaoui

Subjects

*PLANT fibers, *INSULATING materials, *THERMAL insulation, *NATURAL fibers, *NOISE pollution, *ABSORPTION of sound, *DATE palm, *OLIVE

Abstract

The aim of this study is to examine the possibility of using certain plant fibers abundant in Errachidia (southeast of Morocco) as reinforcement in composite materials intended for thermal and acoustic insulation of buildings. For this purpose, a study of the thermo-acoustic properties of some plant fibers derived from date palm by-products (petiole, cluster, trunk, fiber mesh and pinnate leaves) and other vegetable plants (Alfa, reed, fig and olive tree) was carried out. These plant fibers are experimentally characterized using the hot plate and the Kundt tube to measure respectively the thermal conductivity and the sound absorption coefficient. According to the results obtained, the studied vegetal fibers present excellent thermal and acoustic properties. Indeed, the thermal conductivity ranges from 0.065 to 0.091 W/m.K and the sound absorption coefficient varies between 0.6 and 0.9 (average frequencies). Consequently, the use of natural fibers as reinforcement for composites can solve the problems of heat loss and noise nuisance in buildings. [ABSTRACT FROM AUTHOR]

Published

2023

178. Stitches in Time.

Author

WILSON, SAMUEL M.

Subjects

*ANIMAL fibers, *PEPTIDE mass fingerprinting, *PLANT fibers, *FLAXSEED, *PALMS

Abstract

This article explores the historical and cultural significance of needles throughout civilizations. It discusses the use of bone needles by our closest relatives, the Denisovans and Neanderthals, and the complexity of cordage made by Neanderthals. The article also delves into the process of spinning yarn and weaving cloth, as well as the evolution of knitting. It concludes by highlighting the advancements in surgical needles and the use of robotic-assisted microsurgery. Overall, the article emphasizes the importance of needles as essential human artifacts and their role in various aspects of human life, from practicality to art and fashion. [Extracted from the article]

Published

2024

179. Editorial: Molecular and genetic mechanisms of plant architecture regulation.

Author

Wenyi Wang, Weiwei Zhang, Jamil, Muhammad, Jumin Tu, and Lei Huang

Subjects

STOMATA, BOTANY, SMALL ubiquitin-related modifier proteins, PLANT fibers, DROUGHT tolerance, HEAT shock proteins, MOLECULAR biology, SUGARCANE

Abstract

This document is an editorial titled "Molecular and genetic mechanisms of plant architecture regulation" published in the journal Frontiers in Plant Science. The editorial discusses the impact of environmental stressors on sugarcane crops and the molecular and genetic mechanisms that regulate plant architecture. It highlights the effects of temperature, water availability, and light intensity on sugarcane growth and development. The editorial also explores the accumulation of reactive oxygen species (ROS) and the role of stress-related genes and proteins in plant adaptation to environmental stress. Strategies to mitigate environmental stress, such as breeding stress-resistant cultivars and implementing irrigation scheduling, are also discussed. The document emphasizes the importance of molecular breeding methods in improving sugarcane selection and breeding efficiency. [Extracted from the article]

Published

2024

180. General Conclusions

Author

Rao, Sudhakar M. and Rao, Sudhakar M.

Published

2023

181. Stabilizers for Earthen Building Materials

Author

Rao, Sudhakar M. and Rao, Sudhakar M.

Published

2023

182. Material analysis to select a suitable fabric for women's outerwear.

Author

Turgunova, Iroda, Khomidjonova, Nazira, and Khojiev, Abdurakhim

Subjects

*MATERIALS analysis, *PLANT fibers, *SYNTHETIC fibers, *CLOAKING devices, *OUTDOOR clothing, *SPRING

Abstract

The purpose of the study was to select the most suitable material for winter jackets and cloaks for spring and autumn, based on a study of the materials used in modern women's outerwear. Studies have shown that urethane leather fabric is recommended for women to wear from artificial leather fabric, as this fabric does not cause discomfort during light and soft movement and has a longer service life than others. Dekrilan film film was recommended for women's buds from film fabric. This is because the fabric contains plant fibers (cotton or viscose) and synthetic fibers. In addition, special attention is paid to the decoration of the fabric. [ABSTRACT FROM AUTHOR]

Published

2023

183. Plant-Based Spinning.

Author

HATCHER, ANNAMARIE

Subjects

PLANT fibers, NATURAL fibers, SPINNING (Textiles), TEXTILE fibers, FLAX spinning

Abstract

The article focuses on the exploration of plant-based fibers in handspinning, emphasizing that fibers like flax and cotton are not more challenging to spin than wool when their growth, processing into spinnable fiber, and historical spinning techniques are understood. Topics discussed include the classification of plant fibers (bast, seed, and leaf), characteristics of bast fibers like flax, cotton as a seed fiber, and the use of leaf fibers such as sisal and pineapple.

Published

2024

184. The substitute ENSO 16 has low impact on glucose metabolism in healthy humans: a randomized, double-blind, active-controlled, cross-over trial

Author

Lutnik, Martin, Weisshaar, Stefan, Mussbacher, Lena M., Steiner, Daniel, and Wolzt, Michael

Published

2024

185. Assessing the impact of plant fibers on swelling parameters of two varieties of expansive soil

Author

Ahlam EL Majid, Khadija Baba, and Yassine Razzouk

Subjects

Expansive soil, Plant fibers, Odometer tests, Clay, Marl, Environmental engineering, TA170-171, Chemical engineering, TP155-156

Abstract

This study aims to assess plant fibers' efficacy in reducing soil swelling in expansive conditions. Testing on clay and marl soils included incorporating incremental amounts (1%, 3%, 9%, and 18%) of Alfa, jute, and sisal fibers. Without fibers, significant soil swelling occurred, but their inclusion effectively mitigated the issue. Sisal fibers showed the highest effectiveness at 18%, followed by jute fibers, and then Alfa fibers. Combining different fiber types improved overall stability. Clay soils outperformed marl soils. Findings highlight the cost-effectiveness and eco-friendliness of plant fibers as a solution against soil swelling.

Published

2023

186. The pectinolytic activity of Burkholderia cepacia and its application in the bioscouring of cotton knit fabric.

Author

Shoily, Sabrina Samad, Fatema, Kaniz, Dina, Rasheda Begum, Biswas, Anik, Haque, Papia, Rahman, Mohammed Mizanur, Uddin, Md. Zulhash, and Sajib, Abu Ashfaqur

Subjects

BURKHOLDERIA cepacia, COTTON, KNIT goods, COTTON textiles, BIOMASS liquefaction, PLANT fibers

Abstract

Background Enzymatic catalysis in different industrial applications is often preferred over chemical methods due to various advantages, such as higher specificity, greater efficiency, and less environmental footprint. Pectinases are a group of enzymes that catalyze the degradation of pectic compounds, the key components of plant middle lamella and the primary cell wall. Pectinases have found applications in multiple industrial processes, including cotton bioscouring, fruit juice extraction and its clarification, plant fiber degumming, paper making, plant biomass liquefaction, and saccharification, among others. The purpose of this study was to taxonomically characterize a bacterial species exhibiting pectinolytic activities and assess its pectinolytic activity qualitatively and quantitatively, as well as test its bioscouring potential. Results Here, we report that Burkholderia cepacia, a previously unknown species with pectinolytic activity, exerts such activity comparable to commercially used pectinase enzymes in the textile industry, but requires less temperature for activity. Conclusion Quantitative evaluation of enzyme activity indicates the potential of the bacterial species for use in the bioscouring of cotton knit fabric. [ABSTRACT FROM AUTHOR]

Published

2023

187. Preparation and characterization of cotton fiber fragments from model textile waste via mechanical milling and enzyme degradation.

Author

Wang, Siyan, Egan, Jeannie, and Salmon, Sonja

Subjects

COTTON fibers, TEXTILE waste, CELLULOSE fibers, COTTON manufacture, DEGREE of polymerization, PLANT fibers, INCINERATION, MECHANICAL alloying

Abstract

Rather than landfilling or incineration, value exists in textile wastes that should be recovered. Cotton is a major component of apparel and other textile materials that could find new value by extracting it from textile waste in the form of cotton fiber fragments (CFFs). To explore this potential, CFF properties were analyzed and compared after producing them from model undyed and fiber reactive dyed textile waste fabrics by mechanical milling or enzymatic degradation. Characterization methods included scanning electron microscopy (SEM), optical microscopy, fiber quality analysis, degree of polymerization (DP), X-ray diffraction, Fourier-transform infrared spectroscopy, and thermogravimetric analysis. Enzyme-treated undyed CFFs exhibited distinct properties of flattened fiber fragment dimensions, a more uniform fiber length distribution compared to other CFFs, a DP comparable to solvent-spun regenerated cellulose fibers from cotton, the highest crystallinity of all CFFs tested, greater hydrophobicity than milled cotton reference material, and better thermal stability than milled reference cotton. The effects of mono-functional and bi-functional reactive dyes on enzyme degradation behavior and final product characteristics were also evaluated and discussed. Both dyed and undyed CFFs show good potential for being utilized in diverse applications. This analysis of the properties of partially degraded cotton fibers provides a necessary technical foundation for promoting CFF recycling for use in applications such as composites and regenerated fibers, and provides insights on the mechanism by which cotton disintegrates in the presence of enzymes to potentially inspire new strategies for dyeing cotton that takes a designed for recycling perspective into account. [ABSTRACT FROM AUTHOR]

Published

2023

188. Modelling the degradation of acidic and alkaline printing paper.

Author

Tétreault, J., Vedoy, D., Bégin, P., Paris Lacombe, S., and Dupont, A.-L.

Subjects

DEGREE of polymerization, CHEMICAL properties, TENSILE strength, COTTON quality, COTTON fibers, FILTER paper, PLANT fibers

Abstract

There has always been an interest in the professional communities of libraries, archives and conservation science to find ways of estimating the rate of degradation of paper under archival conservation conditions. Previously we reported a number of considerations for developing a kinetic degradation model based on Whatman no.1 paper. In the present research, this model was extended to 10 different papers and validated. Various physical and chemical properties of acidic, neutral, and alkaline papers were measured, such as the degree of polymerization (DP), tensile strength, equilibrium moisture content, and pH, as well as alkaline fillers content when applicable. The activation energy (Ea) based on DP of cellulose and zero-span tensile strength were determined. Ea and pH had the most significant influence on the simulated decay of paper. Papers with a high Ea (> 120 kJ mol−1), alkaline such as those containing at least 2% CaCO3, and acidic—but good printing quality papers made of bleached chemical pulp– were found the most durable in ambient conditions. Papers with a lower Ea (< 110 kJ mol−1) such as lignocellulosic papers containing significant amount of mechanical pulp were much less stable over time. Whatman filter papers, used as models of pure cellulosic papers, were found to have low Ea despite the good quality cotton fibers. A generic isoperm equation based on Ea was developed to predict the changes in the state of papers under various climatic conditions, and was applicable independently of the pH of the paper. The model developed allows a better quantification of the deterioration rate of printing papers such as those that are currently, and will be in the future, found in our archival collections. [ABSTRACT FROM AUTHOR]

Published

2023

189. DESIGNING NOVEL, VALUABLE, AND MARKETABLE PRODUCTS FROM WASTE SEDGE PLANT FIBER RESIDUES.

Author

Roadkasamsri, Vuthipong, Teekalee, Apiched, Sungvondee, Arnon, and Yingfeng Li

Subjects

PLANT fibers, PLANT residues, CYPERACEAE, STOCK price indexes

Published

2023

190. SOCIOECONOMIC FACTORS AFFECTING SIWALAN SUGAR BUSINESS INCOME Case study in Jadung Village, Dungkek District, Sumenep Regency.

Author

Ainorrofiqie and Qosasi, Annisa Zhafarina

Subjects

*SOCIOECONOMICS, *SUGAR industry, *AGRICULTURAL industries, *PLANT fibers, *QUANTITATIVE research

Abstract

Siwalan is one of the community's agricultural crops, where this plant is often found in rural areas, and this plant is one of the crops that are managed in the small-scale agricultural business sector, the management of this agricultural business sector is classified as traditional both in terms of management methods and tools, because this business sector is an agricultural business that has been passed down from generation to generation. Palm plants are very beneficial for rural communities, because from all parts of the palm plant can almost be used. The results that can be produced from this plant are sap and palm fiber. The purpose of this research is the first to determine the factors that affect palm sugar business income, the second to determine the most dominant factors that affect palm sugar business income. This type of research is a quantitative study using multiple linear regression analysis method. The object of this research is Jadung Village, Dungkek District, Sumenep Regency with a research sample of 70 respondents. The results showed that the variables age, education, length of business, number of dependents, number of trees, and cosmopolitan level had a significant effect on palm sugar business income. Based on the results of research on socioeconomic factors that affect palm sugar business income, it shows that. Socio-economic factors that affect palm sugar business income are age, education, length of business, family dependents, number of trees and cosmopolitan level, both jointly and partially. The most dominant factor that affects palm sugar business income in Jadung Village, Dungkek District, Sumenep Regency is the Number of Trees Factor, this can be seen from the amount of the beta coefficient variable the number of trees which is 0.396 greater than the others. [ABSTRACT FROM AUTHOR]

Published

2023

191. Durability and Accelerated Ageing of Natural Fibers in Concrete as a Sustainable Construction Material.

Author

Jamshaid, Hafsa, Ali, Husnain, Mishra, Rajesh Kumar, Nazari, Shabnam, and Chandan, Vijay

Subjects

*NATURAL fibers, *SISAL (Fiber), *CONCRETE construction, *SUSTAINABLE construction, *FIBER-reinforced concrete, *PLANT fibers, *CEMENT composites

Abstract

This paper presents an experimental study on the influence of alkaline environments on natural fibers of plant and mineral origin in concretes. The durability of concrete-based composite materials is influenced by the properties of the reinforcing fiber, and the serviceability of concrete is dependent on its durability. The aim of the present study is to investigate the strength, weight loss %, and surface degradation of jute, sugarcane, coconut, sisal, as well as basalt fibers through an accelerated aging method when used as reinforcements in concrete. The samples were immersed in an alkaline environment of sodium and calcium hydroxide at two different levels of pH for one week. Further, the fibers were immersed in NaOH and Ca(OH)2 solutions of 1 M, 2 M, 4 M, and 6 M concentrations for 48 h in order to investigate the gradual effect of an alkaline environment on the mechanical properties of the fiber. It was concluded that the weight loss % was greatest for jute fibers when used in concrete composite, while there was no significant effect on the basalt fiber samples. The strength of jute fiber in the concrete sample was also most severely affected by the aging process, compared to other fibers. The strength of basalt fibers in a concrete composite was least affected by the aging process. In some cases, the sisal fiber sample showed an increase in fiber tenacity after the aging process due to fibrillation, which might have increased the interfacial area. The fiber microstructure before and after the aging was evaluated through the use of scanning electron microscopy (SEM). SEM analyses of different fibers were carried out to investigate surface degradation. The fiber pull-out strength was found to be the greatest for basalt fiber, followed by jute and sisal. This is indicative of the excellent adhesion of such fibers with cement in a concrete composite. In these cases, the use of sisal fiber results in defibrillation and increased specific surface area. Sugarcane and coconut fibers ruptured due to their inherent weakness and provided only a small increment in the mechanical performance of the concrete. Basalt fiber-reinforced concrete offered the greatest compressive strength, followed by jute and sisal. These observations provide crucial information regarding the durability and aging of natural fiber-reinforced concrete. [ABSTRACT FROM AUTHOR]

Published

2023

192. Bast Fiber Decortication for Biocomposites by a Mastication Process.

Author

Walczyk, Daniel, Yang, Jiachen, and Jenkins, Jennifer Gilbert

Subjects

*MASTICATION, *SUSTAINABILITY, *FRACTURE healing, *FLAX, *PLANT fibers, *EXPERIMENTAL design

Abstract

This paper discusses a new method for decorticating bast fiber stalks, particularly hemp and flax, through a mastication process without damaging the fiber for use in biocomposites. Conventional automated decortication methods provide high stalk processing throughput, but they significantly damage the bast fibers and adversely affect their performance in biocomposite applications. Initial experiments with industrial hemp using a matched set of tools indicate that indexing the stalk by, at most, half a tooling period for each mastication cycle maximizes both the crushed stalk flexing action and dehurding efficiency. Further process insight was gained through simple stalk-crushing experiments (force vs. deflection) between matching teeth with no indexing, where force spikes correspond to initial collapse of the stalk cross section and initial hurd bending fracture along the stalk length. A more extensive experimental design with stiffer tooling reveals that hurding efficiency is maximized by adding spaces in the bottom die for hurd to fall through, using the smallest practical indexing distance of less than half a tooling period, and using as many teeth as possible. However, shorter indexing and more teeth also decrease the throughput rate and complicate stalk handling. Future work for optimizing and commercializing the process is suggested. [ABSTRACT FROM AUTHOR]

Published

2023

193. Fiber intake and risk of chronic obstructive pulmonary disease: A systematic review and dose response meta‐analysis.

Author

Valisoltani, Neda, Ghoreishy, Seyed Mojtaba, Imani, Hossein, Rajabi Harsini, Asma, Jowshan, Mohammadreza, Travica, Nikolaj, and Mohammadi, Hamed

Subjects

*CHRONIC obstructive pulmonary disease, *PLANT fibers, *RANDOM effects model, *FIBERS, *FRUIT yield, *DIETARY fiber

Abstract

This systematic review and dose–response meta‐analysis examined the risk of chronic obstructive pulmonary disease (COPD) following dietary fiber intake. Relevant articles were retrieved from a variety of databases, including Scopus, Embase, and Medline, until March 2023. Spirometry was the most frequently used method for determining the presence of COPD. Based on the search, there were a total of 213,912 participants across five separate studies. Random effects model was used to combine the data and a dose–response analysis was further conducted. Five distinct cohort studies were identified. Based on highest versus lowest analysis, there was an inverse correlation between the intake of total fiber (RR, 0.72; 95%, CI: 0.64–0.80), cereal fiber (RR: 0.76, 95% CI 0.68, 0.86), and fruit fiber (RR: 0.75, 95% CI: 0.68, 0.83). Although this result was not significant for vegetable fiber (RR, 0.95; 95% CI, 0.84–1.07). Dose–response analysis revealed that daily increase of 10 g of total dietary fiber, cereal fiber, or fruit fiber reduced the risk of COPD by 26%, 21%, and 37%, respectively. The ROBINS‐E tool classified all cohort studies as having a moderate risk of bias. Total fiber, cereal fiber, and fruit fiber intake were found to have low credibility using the NutriGrade tool. Additionally, there is a lack of scientific evidence supporting the use of vegetable fiber. Larger, more comprehensive studies are required to confirm these findings. [ABSTRACT FROM AUTHOR]

Published

2023

194. Genome-wide artificial introgressions of Gossypium barbadense into G. hirsutum reveal superior loci for simultaneous improvement of cotton fiber quality and yield traits.

Author

Li, Shaoqi, Kong, Linglei, Xiao, Xianghui, Li, Pengtao, Liu, Aiying, Li, Junwen, Gong, Juwu, Gong, Wankui, Ge, Qun, Shang, Haihong, Pan, Jingtao, Chen, Hong, Peng, Yan, Zhang, Yuanming, Lu, Quanwei, Shi, Yuzhen, and Yuan, Youlu

Subjects

*COTTON, *SEA Island cotton, *COTTON fibers, *COTTON quality, *INTROGRESSION (Genetics), *PLANT fibers, *LOCUS (Genetics), *GENETIC correlations

Abstract

[Display omitted] • Genome-wide introgressions were beneficial to the comprehensive mining of QTL. • The combination of CSSLs and improved k-mer genotyping showed the high efficiency for genetic effects detection. • 39 introgression segments were detected with stable favorable effects for simultaneous improvement of multiple traits in Gh. • 11 segments were comprehensive discovered for the stable simultaneous improvement of FL/FS and LP. • The plasticity of genetic effects of variations in different genetic backgrounds need to be considered in breeding. The simultaneous improvement of fiber quality and yield for cotton is strongly limited by the narrow genetic backgrounds of Gossypium hirsutum (Gh) and the negative genetic correlations among traits. An effective way to overcome the bottlenecks is to introgress the favorable alleles of Gossypium barbadense (Gb) for fiber quality into Gh with high yield. This study was to identify superior loci for the improvement of fiber quality and yield. Two sets of chromosome segment substitution lines (CSSLs) were generated by crossing Hai1 (Gb , donor-parent) with cultivar CCRI36 (Gh) and CCRI45 (Gh) as genetic backgrounds, and cultivated in 6 and 8 environments, respectively. The kmer genotyping strategy was improved and applied to the population genetic analysis of 743 genomic sequencing data. A progeny segregating population was constructed to validate genetic effects of the candidate loci. A total of 68,912 and 83,352 genome-wide introgressed kmers were identified in the CCRI36 and CCRI45 populations, respectively. Over 90 % introgressions were homologous exchanges and about 21 % were reverse insertions. In total, 291 major introgressed segments were identified with stable genetic effects, of which 66(22.98 %), 64(21.99 %), 35(12.03 %), 31(10.65 %) and 18(6.19 %) were beneficial for the improvement of fiber length (FL), strength (FS), micronaire, lint-percentage (LP) and boll-weight, respectively. Thirty-nine introgression segments were detected with stable favorable additive effects for simultaneous improvement of 2 or more traits in Gh genetic background, including 6 could increase FL/FS and LP. The pyramiding effects of 3 pleiotropic segments (A07:C45Clu-081, D06:C45Clu-218, D02:C45Clu-193) were further validated in the segregating population. The combining of genome-wide introgressions and kmer genotyping strategy showed significant advantages in exploring genetic resources. Through the genome-wide comprehensive mining, a total of 11 clusters (segments) were discovered for the stable simultaneous improvement of FL/FS and LP, which should be paid more attention in the future. [ABSTRACT FROM AUTHOR]

Published

2023

195. Integration of refining and in situ growth of silver nanoparticles for improving the antibacterial and antiviral performance of plant fibers.

Author

Hu, Yuantao, Lin, Changmei, Lan, Jinxin, Huang, Hai, Chen, Jiazhen, Wu, Yao, Ma, Xiaojuan, and Cao, Shilin

Subjects

PLANT fibers, PLANT performance, SILVER nanoparticles, CELLULOSE fibers, ANTIBACTERIAL agents, HYDROXYL group

Abstract

The prevalence of the new crown epidemic has deepened people's awareness of the importance of antibacterial and antiviral materials. It is imperative to develop applicable and economical antibacterial materials. In this work, we have proposed a facile method to prepare plant fibers with prominent antibacterial and antiviral performance. In the proposed strategy, the fiber design and in situ assembly of silver nanoparticles (AgNPs) were applied to improve the antibacterial and antiviral performance of plant fibers. Mechanical refining split the fibers and made them conformable; in this instance, polydopamine (PDA) was precipitated onto the fiber surface by the oxidative polymerization of dopamine and linked closely with cellulose hydroxyl groups, while AgNPs were in situ grown on the PDA coatings; PDA acted as a bonder to link fibers and AgNPs together. Benefiting from the high AgNP loadings and strong bond between AgNPs and fibers, the fibers showed excellent antibacterial and antiviral performance. This study provides a novel route for improving the antibacterial performance of plant fibers. [ABSTRACT FROM AUTHOR]

Published

2023

196. Optimizing Polymer-Stabilized Raw Earth Composites with Plant Fibers Reinforcement for Historic Building Rehabilitation.

Author

Menadi, Souad, Hadidane, Yazid, Benzerara, Mohammed, Saidani, Messaoud, Khorami, Morteza, Belouettar, Redjem, Slimani, Fayçal, Gouider, Nadia, and Rehab-Bekkouche, Souhila

Subjects

PLANT fibers, BUILDING reinforcement, ASTERACEAE, MECHANICAL behavior of materials, FIBROUS composites, HISTORIC buildings, NATURAL fibers, PHOTOVOLTAIC power systems

Abstract

This research focuses on the optimization of formulation, characterization, and damage analysis of plant fiber-reinforced polyester resin composites (jute and date palm). To better understand the characteristics and mechanical behavior of these materials, this study investigates the influence of resin content and plant fibers on the physico-mechanical behavior of the resin composites. Resinous composites consisting of polyester resin and raw earth were studied using a novel formulation based on an empirical method that follows the principle of earth saturation with polyester resin. Saturation was achieved with a 28% content of polyester resin, which appeared to be an optimal blend for the earth–resin composite. Plant fibers were randomly incorporated as reinforcement in the composites at various percentages (1%, 2%, and 3%) and lengths (0.5 cm, 1 cm, and 1.5 cm). Mechanical tests including bending, compression, and indentation were conducted to evaluate the mechanical properties of the composites. Analysis of fracture morphology revealed that the deformation and rupture mechanisms in bending, compression, and indentation of these composites differ from those of traditional concrete and cement mortar. The obtained results indicate that the composites exhibit acceptable performance and could be favorably employed in the rehabilitation of historic buildings. [ABSTRACT FROM AUTHOR]

Published

2023

197. Water aging effects on the flexural properties of fully biobased coir fiber composites.

Author

Assis, Eduardo Geraldo, dos Santos, Júlio Cesar, da Silva, Rodrigo José, de Oliveira, Lívia Ávila, del Pino, Gilberto Garcia, Scarpa, Fabrizio, and Panzera, Túlio Hallak

Subjects

COIR, CASTOR oil plant, NATURAL fibers, WATER immersion, PLANT fibers, FLEXURAL modulus, FIBROUS composites

Abstract

This work describes the flexural behavior of biocomposites composed of a polyurethane matrix derived from castor oil plants and coir fibers. A statistical design is performed to identify the effects of fiber alkaline treatment and aging on the flexural modulus and strength of the composites. Physical tests and failure analyses are carried out to better assess their mechanical performance. A second experiment at 100% relative humidity is performed on treated fiber composites to compare with those obtained by immersion in water. The flexural modulus of the composites is not significantly affected by the fiber alkali treatment, while the strength is reduced by 35.17% when treated fibers are considered. Increasing the exposure time of composites under both aging conditions progressively reduces their flexural properties. The aging process of biocomposites in an environment with 100% relative humidity takes twice as long to reduce to the same flexural properties as those aged in water. Highlights: Composites made with treated fibers showed higher apparent density and lower porosity.Water aging reduces flexural modulus and strength of biobased coir composites.The bending properties are strongly dominated by the properties of biobased polymer.100% relative humidity takes twice as long to reduce to the flexural properties as those aged in water.Untreated coir fibers achieve superior bending properties under moisture aging. [ABSTRACT FROM AUTHOR]

Published

2023

198. Over-expression of GhACTIN1 under the control of GhSCFP promoter improves cotton fiber and yield.

Author

Iqbal, Adnan, Aslam, Sibgha, Akhtar, Sidra, Ali, Qurban, Rao, Abdul Qayyum, and Husnain, Tayyab

Subjects

*COTTON fibers, *PLANT fibers, *WATER efficiency, *SEED yield, *PHOTOSYNTHETIC rates, *COTTONSEED, *BT cotton

Abstract

Actin dynamics is pivotal in controlling cotton fiber elongation and the onset of secondary wall biosynthesis. We report that overexpression of GhACTIN1 under fiber fiber-specific promoter, GhSCFP, improves cotton fiber length, strength, and micronaire value. However, the effect of transgene has a more positive effect on fiber strength and micronaire value than fiber length. F-actin quantification and cellulose contents measurement in transgenic developing cotton fiber during the elongation phase showed an increase of up to 8.7% and 4.7% respectively. Additionally, physiological factors such as water use efficiency showed no significant change in transgenic cotton lines, while stomatal conductance and photosynthetic rate were significantly increased. Moreover, agronomical data determined that lint percentage (GOT) and seed cotton yield also increased up to 4.6% and 29.5% respectively, in transgenic cotton lines compared to the control lines. Our data demonstrate that the GhACTIN1 gene is a strong candidate gene for cotton fiber and yield improvement. [ABSTRACT FROM AUTHOR]

Published

2023

199. Recent Progress on Moisture Absorption Aging of Plant Fiber Reinforced Polymer Composites.

Author

Wang, Quan, Chen, Tuo, Wang, Xiaodong, Zheng, Yue, Zheng, Jiayu, Song, Gaojie, and Liu, Shuyi

Subjects

*FIBROUS composites, *PLANT fibers, *AGING in plants, *MECHANICAL behavior of materials, *MOISTURE, *COMPOSITE materials, *SYNTHETIC fibers

Abstract

Plant fiber reinforced polymer matrix composites have attracted much attention in many industries due to their abundant resources, low cost, biodegradability, and lightweight properties. Compared with synthetic fibers, various plant fibers are easy to obtain and have different characteristics, making them a substitute for synthetic fiber composite materials. However, the aging phenomenon of composite materials has been a key issue that hinders development. In natural environments, moisture absorption performance leads to serious degradation of the mechanical properties of composite materials, which delays the use of composite materials in humid environments. Therefore, the effects of moisture absorption performance of plant fiber composite materials on their mechanical properties have been summarized in this article, as well as various treatment methods to reduce the water absorption of composite materials. [ABSTRACT FROM AUTHOR]

Published

2023

200. The early life immune dynamics and cellular drivers at single-cell resolution in lamb forestomachs and abomasum.

Author

Huang, Kailang, Yang, Bin, Xu, Zebang, Chen, Hongwei, and Wang, Jiakun

Subjects

*MACROPHAGE migration inhibitory factor, *GENE regulatory networks, *CELL analysis, *ANIMAL products, *PLANT fibers, *CELL communication, *LAMBS

Abstract

Background: Four-chambered stomach including the forestomachs (rumen, reticulum, and omasum) and abomasum allows ruminants convert plant fiber into high-quality animal products. The early development of this four-chambered stomach is crucial for the health and well-being of young ruminants, especially the immune development. However, the dynamics of immune development are poorly understood. Results: We investigated the early gene expression patterns across the four-chambered stomach in Hu sheep, at 5, 10, 15, and 25 days of age. We found that forestomachs share similar gene expression patterns, all four stomachs underwent widespread activation of both innate and adaptive immune responses from d 5 to 25, whereas the metabolic function were significantly downregulated with age. We constructed a cell landscape of the four-chambered stomach using single-cell sequencing. Integrating transcriptomic and single-cell transcriptomic analyses revealed that the immune-associated module hub genes were highly expressed in T cells, monocytes and macrophages, as well as the defense-associated module hub genes were highly expressed in endothelial cells in the four-stomach tissues. Moreover, the non-immune cells such as epithelial cells play key roles in immune maturation. Cell communication analysis predicted that in addition to immune cells, non-immune cells recruit immune cells through macrophage migration inhibitory factor signaling in the forestomachs. Conclusions: Our results demonstrate that the immune and defense responses of four stomachs are quickly developing with age in lamb's early life. We also identified the gene expression patterns and functional cells associated with immune development. Additionally, we identified some key receptors and signaling involved in immune regulation. These results help to understand the early life immune development at single-cell resolution, which has implications to develop nutritional manipulation and health management strategies based on specific targets including key receptors and signaling pathways. [ABSTRACT FROM AUTHOR]

Published

2023