mechanical properties – Page 2

Artificial Neural Network Prediction of Mechanical Properties in Mycelium-Based Biocomposites

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Scientists developed an artificial intelligence model that can predict how strong and durable mushroom-based composite materials will be. These composites are made by growing mushroom mycelium (fungal threads) through wood particles and other plant materials, creating an eco-friendly alternative to synthetic materials. The AI model learns from physical measurements and can accurately predict mechanical properties, potentially reducing the need for extensive testing and helping design better sustainable materials.

Tailoring the Mechanical Properties of Fungal Mycelium Mats with Material Extrusion Additive Manufacturing of PHBH and PLA Biopolymers

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Researchers developed a new way to make fungal mushroom mats stronger by printing biodegradable plastic patterns onto them using 3D printing technology. The resulting composite materials combined the sustainability of fungal products with improved strength, making them suitable for flexible applications like smart textiles and lightweight parts. Both tested polymers (PHBH and PLA) enhanced the mycelium’s mechanical properties, with PLA showing superior strength improvements while PHBH offered home compostability.

Strongest untreated mycelium materials produced by Schizophyllum commune dikaryons

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Researchers found that mushroom mycelium grown from dikaryotic strains (with two nuclei) produces stronger, stiffer materials than traditional monokaryon strains used in mycelium-based products. These dikaryotic materials show tensile strength values comparable to some polymers, making them promising for creating sustainable alternatives to leather and textiles. The improved strength comes from differences in cell wall composition and lower expression of a hydrophobin gene, offering new possibilities for bio-based material development.

Artificial Neural Network Prediction of Mechanical Properties in Mycelium-Based Biocomposites

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Researchers used artificial intelligence to predict how strong mushroom-based materials would be. These eco-friendly composites are made from wood particles held together by fungal networks instead of synthetic glue. The AI model successfully learned to predict the strength of these materials based on which type of fungus was used and what wood particles they were grown on, potentially reducing the need for expensive testing.

Shifu-Inspired Fungal Paper Yarns

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Scientists have developed a new method to turn mushroom material into yarn using an ancient Japanese papermaking technique called Shifu. By processing white button mushrooms and rolling the resulting sheets into thread, researchers created yarns with strength comparable to cotton and commercial paper yarns. This innovation opens possibilities for using fungal material in clothing, carpets, and furniture, offering a sustainable alternative to synthetic fibers.

Innovative chitin-glucan based material obtained from mycelium of wood decay fungal strains

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Researchers have developed a new sustainable leather-like material from fungal mycelium that could replace traditional animal leather and synthetic alternatives. By growing specific wood decay fungi in controlled fermentation systems and extracting their chitin and glucan content, they created flexible sheets with mechanical properties similar to real leather. The materials are biodegradable, require no animal farming, and avoid toxic tanning processes, making them a promising eco-friendly solution for fashion and furniture industries.

Study on the Properties and Design Applications of Polyester–Cotton Matrix Mycelium Composite Materials

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Researchers developed eco-friendly composite materials by growing oyster mushroom mycelium on waste polyester-cotton textile fibers. The optimal blend was 65% polyester and 35% cotton, which balanced strength, water resistance, and ability to break down in soil. These materials could replace foam plastics in packaging and home products while helping solve the problem of textile waste.

Anisotropic Growth of Filamentous Fungi in Wood Hydrogel Composites Increases Mechanical Properties

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Researchers developed new composite materials by growing fungi on specially treated wood. The fungi naturally grow along the wood’s fiber direction, creating stronger, more organized structures than they would in regular gelatin. By adjusting the wood type and nutrient levels, scientists could precisely control the mechanical strength of these eco-friendly materials, which could eventually be used in building products and packaging.

Effect of AgNPs on PLA-Based Biocomposites with Polysaccharides: Biodegradability, Antibacterial Activity and Features

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Scientists created a new type of eco-friendly plastic made from PLA (a biodegradable polymer) mixed with silver nanoparticles and natural starches or chitosan. These new materials can kill bacteria and break down naturally in soil within a few months, making them useful for food packaging and medical applications. The addition of silver particles gave the materials antibacterial properties without reducing their ability to biodegrade in natural soil conditions.

Experimental Assessment of Multiple Properties of Mycelium-Based Composites with Sewage Sludge and Bagasse

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Researchers developed a sustainable building material by growing mushroom mycelium (fungal threads) on sewage sludge and bagasse waste. The resulting composites were lightweight, strong enough for highway construction, and environmentally friendly compared to conventional materials made from expanded polystyrene or cement. This innovation offers a promising way to reduce both construction waste and municipal sewage sludge disposal challenges.

Research Topic: mechanical properties