Research News

[Prof. Jeong-yun Sun & Prof. Ho-young Kim] Soft artificial electroreceptors for noncontact spatial perception

Author
김민아
Date
2024-04-29
Views
180

Abstract



Elasmobranch fishes, such as sharks, skates, and rays, use a network of electroreceptors distributed on their skin to locate adjacent prey. The receptors can detect the electric field generated by the biomechanical activity of the prey. By comparing the intensity of the electric fields sensed by each receptor in the network, the animals can perceive the relative positions of the prey without making physical contact. Inspired by this capacity for prey localization, we developed a soft artificial electroreceptor that can detect the relative positions of nearby objects in a noncontact manner by sensing the electric fields that originate from the objects. By wearing the artificial receptor, one can immediately receive spatial information of a nearby object via auditory signals. The soft artificial electroreceptor is expected to expand the ways we can perceive space by providing a sensory modality that did not evolve naturally in human beings.


DISCUSSION



Inspired by how elasmobranch fishes locate their prey in a noncontact manner, we developed a SAER that emulate the ability to sense electric fields. As in the animal’s electroreceptors, ion conductive hydrogels were used as soft electric field receivers. For rapid and elaborate fabrication, network of hydrogel electric field receivers was 3D printed on an elastomer. By covalently anchoring the hydrogels to the elastomer during the printing process, a robust hydrogel/elastomer interface capable of withstanding the mechanical deformation caused by human movement was formed. In the same manner as the electroreceptors of the elasmobranch fishes, the fabricated SAER could detect the relative position of nearby objects in a noncontact manner by comparing the intensity of the object-originated electric fields sensed by each hydrogel receiver in the network. Because electric fields can be transmitted through dielectric materials, the SAER could be used to detect objects even if they were behind a dielectric wall. Moreover, the sensing capability of the SAER was boosted more than 130-fold on the basis of the theoretical analysis. By wearing the SAER, a person can receive spatial information of a nearby object in real time via auditory signals. The artificial electroreceptor expands the way in which humans can perceive space by providing a new sensory modality that did not evolve naturally in human beings.


                                                                                        [Prof. Jeong-yun Sun & Prof. Ho-young Kim]

More Information : Soft artificial electroreceptors for noncontact spatial perception | Science Advances