Passive electrolocation in terrestrial arthropods: Theoretical modelling of location detection
The recent discovery that some terrestrial arthropods can detect, use, and learn from weak electrical fields adds a new dimension to our understanding of how organisms explore and interact with their environments. For bees and spiders, the filiform mechanosensory systems enable this novel sensory mo...
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Veröffentlicht in: | Journal of theoretical biology 2023-02, Vol.558, p.111357-111357, Article 111357 |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | The recent discovery that some terrestrial arthropods can detect, use, and learn from weak electrical fields adds a new dimension to our understanding of how organisms explore and interact with their environments. For bees and spiders, the filiform mechanosensory systems enable this novel sensory modality by carrying electric charge and deflecting in response to electrical fields. This mode of information acquisition opens avenues for previously unrealised sensory dynamics and capabilities. In this paper, we study one such potential: the possibility for an arthropod to locate electrically charged objects.
We begin by illustrating how electrostatic interactions between hairs and surrounding electrical fields enable the process of location detection. After which we examine three scenarios: (1) the determination of the location and magnitude of multiple point charges through a single observation, (2) the learning of electrical and mechanical sensor properties and the characteristics of an electrical field through several observations, (3) the possibility that an observer can infer their location and orientation in a fixed and known electrical field (akin to “stellar navigation”).
To conclude, we discuss the potential of electroreception to endow an animal with thus far unappreciated sensory capabilities, such as the mapping of electrical environments. Electroreception by terrestrial arthropods offers a renewed understanding of the sensory processes carried out by filiform hairs, adding to aero-acoustic sensing and opening up the possibility of new emergent collective dynamics and information acquisition by distributed hair sensors.
•Shows unique sensory capabilities that electroreception enables.•A single hair array can discern the location and magnitude of multiple charges.•Several observations enable learning of an observer’s electrical field properties.•An observer can find their location and orientation within a known electrical field.•Shows how arthropods could map their electrical environment in real-time. |
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ISSN: | 0022-5193 1095-8541 |
DOI: | 10.1016/j.jtbi.2022.111357 |