真菌对水分含量变化的电反应。

Q1 Agricultural and Biological Sciences
Neil Phillips, Antoni Gandia, Andrew Adamatzky
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引用次数: 1

摘要

菌丝体结合复合材料是各种应用中传统材料的潜在替代品,包括隔热和隔音建筑板和产品包装。如果考虑到活菌丝体对环境条件和刺激的反应,就有可能创造出功能性真菌材料。因此,可能会创建主动建筑组件,感官可穿戴设备等。本研究描述了真菌对菌丝结合复合材料含水量变化的电敏感性。当水分含量在[公式:见文]95%和[公式:见文]65%之间,部分干燥时在[公式:见文]15%和[公式:见文]5%之间时,新鲜菌丝结合的复合材料会自发地产生电尖。当菌丝结合复合材料的表面部分或全部被不透水层包裹时,观察到电活动增加。在新鲜的菌丝结合复合材料中,电尖峰可以自发地看到,也可以由表面的水滴诱导。还探讨了电活动与电极深度之间的联系。未来智能建筑、可穿戴设备、基于真菌的传感器和非常规计算机系统的设计可能会受益于真菌的配置和生物制造的灵活性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Electrical response of fungi to changing moisture content.

Mycelium-bound composites are potential alternatives to conventional materials for a variety of applications, including thermal and acoustic building panels and product packaging. If the reactions of live mycelium to environmental conditions and stimuli are taken into account, it is possible to create functioning fungal materials. Thus, active building components, sensory wearables, etc. might be created. This research describes the electrical sensitivity of fungus to changes in the moisture content of a mycelium-bound composite. Trains of electrical spikes initiate spontaneously in fresh mycelium-bound composites with a moisture content between [Formula: see text] 95% and [Formula: see text] 65%, and between [Formula: see text] 15% and [Formula: see text] 5% when partially dried. When the surfaces of mycelium-bound composites were partially or totally encased with an impermeable layer, increased electrical activity was observed. In fresh mycelium-bound composites, electrical spikes were seen both spontaneously and when induced by water droplets on the surface. Also explored is the link between electrical activity and electrode depth. Future designs of smart buildings, wearables, fungi-based sensors, and unconventional computer systems may benefit from fungi configurations and biofabrication flexibility.

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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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