细菌纤维素增强菌丝复合材料的机械特性。

Q1 Agricultural and Biological Sciences
Elise Elsacker, Simon Vandelook, Bastien Damsin, Aurélie Van Wylick, Eveline Peeters, Lars De Laet
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引用次数: 0

摘要

背景:虽然菌丝体被认为是木质纤维素材料中化石基树脂的理想替代品,但由于菌丝体与天然纤维之间的内部结合力较弱等原因,菌丝体复合材料的机械性能仍不理想。将菌丝体材料与有机添加剂混合可提供一种解决方案。更具体地说,细菌纤维素似乎是一种很有前景的添加剂,可以增强菌丝复合材料的强度:结果:在这项研究中,我们着手调查了菌丝复合材料的机械性能,这些复合材料由白腐真菌 Trametes versicolor 生产,并添加了细菌纤维素作为有机添加剂。我们建立了一个方法论框架,以细菌纤维素和大麻组成的混合基质为基础,结合热压方法,轻松生产细菌纤维素,并随后制造菌丝复合刨花板。我们发现,添加细菌纤维素后,复合刨花板的内部粘结性明显改善:结论:在菌丝复合材料中添加细菌纤维素不仅能加强菌丝材料的内部粘合力,还能调整材料的机械性能。因此,这项研究有助于不断开发具有高性能机械特性的全生物混合材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mechanical characteristics of bacterial cellulose-reinforced mycelium composite materials.

Background: While mycelium is considered a promising alternative for fossil-based resins in lignocellulosic materials, the mechanical properties of mycelium composite materials remain suboptimal, among other reasons due to the weak internal bonds between the hyphae and the natural fibres. A solution could be provided by the hybridisation of mycelium materials with organic additives. More specifically, bacterial cellulose seems to be a promising additive that could result in reinforcing mycelium composites; however, this strategy is underreported in scientific literature.

Results: In this study, we set out to investigate the mechanical properties of mycelium composites, produced with the white-rot fungus Trametes versicolor, and supplemented with bacterial cellulose as an organic additive. A methodological framework is developed for the facile production of bacterial cellulose and subsequent fabrication of mycelium composite particle boards based on a hybrid substrate consisting of bacterial cellulose and hemp in combination with a heat-pressing approach. We found that, upon adding bacterial cellulose, the internal bond of the composite particle boards significantly improved.

Conclusions: The addition of bacterial cellulose to mycelium composite materials not only results in a strengthening of internal bonding of mycelium material, but also renders tuneable mechanical properties to the material. As such, this study contributes to the ongoing development of fully biological hybrid materials with performant mechanical characteristics.

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来源期刊
Fungal Biology and Biotechnology
Fungal Biology and Biotechnology Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics
CiteScore
10.20
自引率
0.00%
发文量
17
审稿时长
9 weeks
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