Evaluating the Effects of Pineapple Fiber, Potato Waste Filler, Surface Treatment, and Fiber length on the Mechanical Properties of Polyethylene Composites for Biomedical Applications

Results in Engineering, Год журнала: 2024, Номер unknown, С. 102974 - 102974

Опубликована: Сен. 1, 2024

Язык: Английский

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Recent Advances in Natural Fiber Reinforced Metal/Cement/Polymer Composites: An Overview of the Structure-Property Relationship for Engineering Applications.

Hybrid Advances, Год журнала: 2025, Номер unknown, С. 100378 - 100378

Опубликована: Янв. 1, 2025

Язык: Английский

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Evaluation of Grewia optiva Fiber as a Sustainable and High-Performance Reinforcement Material for Composite Applications

Results in Engineering, Год журнала: 2025, Номер unknown, С. 104096 - 104096

Опубликована: Янв. 1, 2025

Язык: Английский

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An experimental and numerical study of the ballistic behavior of an epoxy matrix hybrid composite reinforced with aramid fabric and fique fabric

Journal of Materials Research and Technology, Год журнала: 2025, Номер unknown

Опубликована: Янв. 1, 2025

Язык: Английский

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Development of Bambusa tulda fiber-micro particle reinforced hybrid green composite: A sustainable solution for tomorrow's challenges in construction and building engineering

Construction and Building Materials, Год журнала: 2024, Номер 441, С. 137486 - 137486

Опубликована: Июль 24, 2024

Язык: Английский

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Sustainable Innovations: Mechanical and Thermal Stability in Palm Fiber-Reinforced Boron Carbide Epoxy Composites

Results in Engineering, Год журнала: 2024, Номер unknown, С. 103214 - 103214

Опубликована: Окт. 1, 2024

Язык: Английский

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Catalytic and biomedical applications of nanocelluloses: A review of recent developments

International Journal of Biological Macromolecules, Год журнала: 2024, Номер 268, С. 131829 - 131829

Опубликована: Апрель 25, 2024

Nanocelluloses exhibit immense potential in catalytic and biomedical applications. Their unique properties, biocompatibility, versatility make them valuable various industries, contributing to advancements environmental sustainability, catalysis, energy conversion, drug delivery, tissue engineering, biosensing/imaging, wound healing/dressings. Nanocellulose-based catalysts can efficiently remove pollutants from contaminated environments, sustainable cleaner ecosystems. These materials also be utilized as carriers, enabling targeted controlled release. high surface area allows for efficient loading of therapeutic agents, while their biodegradability ensures safer gradual release within the body. delivery systems enhance efficacy treatments minimizes side effects. Moreover, nanocelluloses serve scaffolds engineering due structural integrity biocompatibility. They provide a three-dimensional framework cell growth regeneration, promoting development functional biologically relevant tissues. dressings have shown great promise healing dressings. ability absorb exudates, maintain moist environment, promote proliferation migration accelerates process. Herein, recent pertaining applications composites are deliberated, focusing on important challenges, advantages, limitations, future prospects.

Язык: Английский

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Characterization of a Novel Natural Fiber Extracted from Albizia julibrissin Plant Stem: Advancing Sustainable Product Development

Results in Engineering, Год журнала: 2024, Номер unknown, С. 103737 - 103737

Опубликована: Дек. 1, 2024

Язык: Английский

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Carbon material-based thermoelectric ultra-high-performance alkali-activated concrete

Composites Part B Engineering, Год журнала: 2025, Номер unknown, С. 112279 - 112279

Опубликована: Фев. 1, 2025

Язык: Английский

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Advancing Textile Waste Recycling: Challenges and Opportunities Across Polymer and Non-Polymer Fiber Types

Polymers, Год журнала: 2025, Номер 17(5), С. 628 - 628

Опубликована: Фев. 26, 2025

The growing environmental impact of textile waste, fueled by the rapid rise in global fiber production, underscores urgent need for sustainable end-of-life solutions. This review explores cutting-edge pathways waste management, spotlighting innovations that reduce reliance on incineration and landfilling while driving material circularity. It highlights advancements collection, sorting, pretreatment technologies, as well both established emerging recycling methods. Smart collection systems utilizing tags sensors show great promise streamlining logistics automating pick-up routes transactions. For automated technologies like near-infrared hyperspectral imaging lead way accurate scalable separation. Automated disassembly techniques are effective at removing problematic elements, though other pretreatments, such color finish removal, still to be customized specific streams. Mechanical is ideal textiles with strong mechanical properties but has limitations, particularly blended fabrics, cannot repeated endlessly. Polymer recycling-through melting or dissolving polymers-produces higher-quality recycled materials comes high energy solvent demands. Chemical recycling, especially solvolysis pyrolysis, excels breaking down synthetic polymers polyester, potential yield virgin-quality monomers. Meanwhile, biological methods, their infancy, natural fibers cotton wool. When methods not viable, gasification can used convert into synthesis gas. concludes future hinges integrating sorting advancing solvent-based chemical technologies. These innovations, supported eco-design principles, progressive policies, industry collaboration, essential building a resilient, circular economy.

Язык: Английский

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