Ferroelectric‐Assisted Ion Dynamics for Prolonged Tactile Cognizance in a Biomimetic Memory‐in‐Sensor System

Ferroelectric‐Assisted Ion Dynamics for Prolonged Tactile Cognizance in a Biomimetic Memory‐in‐Sensor System

Abstract The advancements in developing low‐powered artificial tactile cognition devices, inspired by the iontronic‐reliant human haptic sensory system, show great potential in future robotics and prosthetics. However, poor tactile memory and the complexity of integrating diverse modules for tactile...

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Bibliographic Details
Main Authors: Ritamay Bhunia, Joo Sung Kim, Hayoung Oh, Dong Jun Kim, Seokyeong Lee, Cheolmin Park, Do Hwan Kim
Format: Article
Language:English
Published: Wiley-VCH 2025-04-01
Series:Advanced Electronic Materials
Subjects:
ferroelectric‐assisted ion dynamics
neuromorphic devices
organic electrochemical transistor
tactile memory‐in‐sensor
Online Access:https://doi.org/10.1002/aelm.202400550
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Summary:Abstract The advancements in developing low‐powered artificial tactile cognition devices, inspired by the iontronic‐reliant human haptic sensory system, show great potential in future robotics and prosthetics. However, poor tactile memory and the complexity of integrating diverse modules for tactile sensing and neuromorphic functionalities pose a formidable challenge. Here, a mechanoreceptor‐inspired tactile memory‐in‐sensor (TMIS) device is presented, employing ferroelectric‐assisted ion dynamics (FAID) in FAID‐based synaptic tactile transistor (FAID‐STT). This approach improves the long‐term memory (LTM) of tactile information while minimizing power consumption, all within a unified device architecture of TMIS. The FAID mechanism intricately combines the release of trapped ions solely under mechanical stress with remnant ferroelectric polarization induced by voltage stimulation, ensuring prolonged memory retention. Consequently, the FAID‐STT exhibits a voltage‐dependent memory effect stemming from the augmentation of ferroelectric dipole polarization, offering uninterrupted tactile memory for over 12 min without requiring additional power inputs for memory retention.
ISSN:2199-160X

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