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Flexible Artificial Mechanoreceptor Based on Microwave Annealed Morphotropic Phase Boundary of HfxZr1‐xO2 Thin Film

The development of artificial tactile receptor systems is important in the fields of prosthetic devices, interfaces for the metaverse, and sensors. A pressure sensor and memory device may be used in this system to replicate the tactile detecting capabilities of human skin. The implementation of syst...

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Bibliographic Details
Published in:Advanced electronic materials 2024-02, Vol.10 (2), p.n/a
Main Authors: Jung, Minhyun, Kim, Seungyeob, Hwang, Junghyeon, Kim, Hye Jin, Kim, Yunjeong, Ahn, Jinho, Jeon, Sanghun
Format: Article
Language:English
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Summary:The development of artificial tactile receptor systems is important in the fields of prosthetic devices, interfaces for the metaverse, and sensors. A pressure sensor and memory device may be used in this system to replicate the tactile detecting capabilities of human skin. The implementation of systems that take into account mass production and miniaturization is still difficult. Here, a flexible artificial tactile receptor built using conventional semiconductor processes that combine a vertically stacked piezoelectric sensor with neuromorphic memory is presented. As a fundamental component for both sensors and memory, hafnium zirconium oxide (HZO) formed by using semiconductor deposition technique is introduced. Due to its exceptional piezoelectric performance, the morphotropic phase boundary of HZO is studied. The entire materials and processes are highly compatible with conventional semiconductor processes, including microwave annealing‐based low‐temperature crystallization. Even after 10,000 times of bending stress, the sensor and memory constructed on a flexible substrate exhibit consistent pressure detection characteristics over a wide range of 2–25 kPa. The feasibility of the approach is further demonstrated by a deep neural network simulation, which reached 90.8% braille recognition accuracy. Wearable electronics and medical devices are two examples of industrial domains that can use these flexible, exceptionally durable devices. In this study, a microwave‐annealed hafnium zirconium oxide thin film is used to fabricate a flexible artificial mechano receptor system. By adopting a vertically stacked piezoelectric sensor with neuromorphic memory, pressure‐response mechano receptor characteristics are successfully demonstrated. These approaches for building neuromorphic sensors based on semiconductor processes can be adopted in various fields including haptic displays, user interfaces, healthcare, and robotics.
ISSN:2199-160X
2199-160X
DOI:10.1002/aelm.202300594