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Electrolyte-free potassium ions intercalated in 2D layered metal oxide for imitating spatiotemporal biological neural dynamics

Authors
Noh, GichangKim, JeonghoWoo, Dong YeonKim, Min-gyuYoo, HyeriJeong, Han BeomJo, YooyeonPark, EunpyoLee, Dae KyuKim, Min JeeJo, Min-kyungKim, In SooKasirga, Talip SerkanHa, Dong HanKim, Soo YoungHwang, Gyu WeonKim, SangtaeLee, Chul-HoYang, HeejunJeong, Hu YoungKang, KibumKwak, Joon Young
Issue Date
Jun-2025
Publisher
ELSEVIER SCI LTD
Citation
MATERIALS TODAY, v.85, pp 27 - 38
Pages
12
Indexed
SCIE
SCOPUS
Journal Title
MATERIALS TODAY
Volume
85
Start Page
27
End Page
38
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/212969
DOI
10.1016/j.mattod.2025.02.008
ISSN
1369-7021
1873-4103
Abstract
Alkali ions are crucial to physiological neural activities and their dynamics can be implemented in various iontronics. For the host materials for alkali ions, 2D layered materials have become the preferred choice thanks to their facilitating ion accommodation and movement between layers. Nevertheless, challenges such as the need for external electrolytes, pre-fabrication for ion intercalation, and thermodynamic stability during ion movements still persist. Consequently, the comprehensive understanding of the electrical dynamics associated with alkali ion movement has rarely been demonstrated in 2D layered materials so far. Here, we engineered an electrolyte-free high-crystalline 2D layered MnO2 nanoplate with potassium ions by metal–organic chemical vapor deposition. The combination of potassium ions and layered MnO2 exhibits electrically induced ion migration coupled with a subsequent phase transition, resulting in negative differential resistance. Furthermore, the material's distinct hybrid plasticity, driven by its ion dynamics, provides a sophisticated platform for sequential motion recognition, valuable for assessing continuous motion across varied subjects. Finally, we demonstrate the broad applicability of our 2D K-MnO2 and highlight its versatility in spatiotemporal ion modulation within three-terminal structures, showing potential for future advancements.
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COLLEGE OF ENGINEERING (DEPARTMENT OF NUCLEAR ENGINEERING)
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