Fungal electronics

Andrew Adamatzky; Phil Ayres; Alexander E. Beasley; Alessandro; Chiolerio; Mohammad M. Dehshibi; Antoni Gandia; Elena Albergati; Richard; Mayne; Anna Nikolaidou; Nic Roberts; Martin Tegelaar; Michail-Antisthenis; Tsompanas; Neil Phillips; Han A. B. W\"osten

arXiv:2111.11231·cs.ET·November 23, 2021

Fungal electronics

Andrew Adamatzky, Phil Ayres, Alexander E. Beasley, Alessandro, Chiolerio, Mohammad M. Dehshibi, Antoni Gandia, Elena Albergati, Richard, Mayne, Anna Nikolaidou, Nic Roberts, Martin Tegelaar, Michail-Antisthenis, Tsompanas, Neil Phillips, Han A. B. W\"osten

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Open Access

TL;DR

Fungal electronics utilize living mycelium to create adaptable electronic devices capable of sensing and computing, with potential applications in wearable technology and embedded systems.

Contribution

This paper introduces fungal electronics as a new class of living devices that can change impedance and generate electrical signals in response to external stimuli.

Findings

01

Fungal electronics can be integrated into materials and wearables.

02

They can function as stand-alone sensing and computing devices.

03

They exhibit dynamic electrical properties in response to external controls.

Abstract

Fungal electronics is a family of living electronic devices made of mycelium bound composites or pure mycelium. Fungal electronic devices are capable of changing their impedance and generating spikes of electrical potential in response to external control parameters. Fungal electronics can be embedded into fungal materials and wearables or used as stand alone sensing and computing devices.

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Taxonomy

TopicsPlant and Biological Electrophysiology Studies · Slime Mold and Myxomycetes Research