Low-density, water-repellent, and thermally insulating cellulose-mycelium foams

IF 4.9 2区工程技术 Q1 MATERIALS SCIENCE, PAPER & WOOD

Cellulose Pub Date : 2024-08-28 DOI:10.1007/s10570-024-06067-5

Philippe Amstislavski, Tiina Pöhler, Anniina Valtonen, Lisa Wikström, Ali Harlin, Satu Salo, Petri Jetsu, Géza R. Szilvay

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Abstract

This work explored whether partial cellulose bioconversion with fungal mycelium can improve the properties of cellulose fibre-based materials. We demonstrate an efficient approach for producing cellulose-mycelium composites utilizing several cellulosic matrices and show that these materials can match fossil-derived polymeric foams on water contact angle, compression strength, thermal conductivity, and exhibit selective antimicrobial properties. Fossil-based polymeric foams commonly used for these applications are highly carbon positive, persist in soils and water, and are challenging to recycle. Bio-based alternatives to synthetic polymers could reduce GHG emissions, store carbon, and decrease plastic pollution. We explored several fungal species for the biofabrication of three kinds of cellulosic-mycelium composites and characterized the resulting materials for density, microstructure, compression strength, thermal conductivity, water contact angle, and antimicrobial properties. Foamed mycelium-cellulose samples had low densities (0.058 – 0.077 g/cm³), low thermal conductivity (0.03 – 0.06 W/m∙K at + 10 °C), and high water contact angle (118 – 140°). The recovery from compression of all samples was not affected by the mycelium addition and varied between 70 and 85%. In addition, an antiviral property against active MS-2 viruses was observed. These findings show that the biofabrication process using mycelium can provide water repellency and antiviral properties to cellulose foam materials while retaining their low density and good thermal insulation properties.

Graphical Abstract

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低密度、憎水、隔热纤维素菌丝泡沫塑料

这项研究探讨了部分纤维素与真菌菌丝体的生物转化能否改善纤维素纤维基材料的性能。我们展示了一种利用多种纤维素基质生产纤维素-菌丝体复合材料的有效方法，并表明这些材料在水接触角、压缩强度、导热性能方面可与化石来源的聚合物泡沫相媲美，并具有选择性抗菌特性。这些应用中常用的化石基聚合泡沫具有高碳正性，在土壤和水中持久存在，并且难以回收利用。合成聚合物的生物基替代品可以减少温室气体排放、储存碳和减少塑料污染。我们研究了几种真菌用于生物制造三种纤维素-菌丝复合材料的方法，并对所得材料的密度、微观结构、压缩强度、导热性、水接触角和抗菌特性进行了表征。发泡的菌丝体-纤维素样品密度低（0.058 - 0.077 g/cm3），导热率低（+ 10 °C 时为 0.03 - 0.06 W/m∙K），水接触角高（118 - 140°）。所有样品的压缩回收率都不受菌丝体添加量的影响，在 70% 到 85% 之间。此外，还观察到了对活性 MS-2 病毒的抗病毒特性。这些研究结果表明，使用菌丝体的生物制造工艺可为纤维素泡沫材料提供防水和抗病毒特性，同时保持其低密度和良好的隔热性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cellulose 工程技术-材料科学：纺织

CiteScore

10.10

自引率

10.50%

发文量

580

审稿时长

3-8 weeks

期刊介绍： Cellulose is an international journal devoted to the dissemination of research and scientific and technological progress in the field of cellulose and related naturally occurring polymers. The journal is concerned with the pure and applied science of cellulose and related materials, and also with the development of relevant new technologies. This includes the chemistry, biochemistry, physics and materials science of cellulose and its sources, including wood and other biomass resources, and their derivatives. Coverage extends to the conversion of these polymers and resources into manufactured goods, such as pulp, paper, textiles, and manufactured as well natural fibers, and to the chemistry of materials used in their processing. Cellulose publishes review articles, research papers, and technical notes.