Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application
Covalent organic polymer (COP) thin film-based memristors have generated intensive research interest, but the studies are still in their infancy. Herein, by controlling the content of hydroxyl groups in the aldehyde monomer, Py-COP thin films with different electronic push-pull effects were fabricat...
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sg-ntu-dr.10356-1758192024-05-07T05:04:12Z Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application Zhou, Panke Yu, Hong Chee, Mun Yin Zeng, Tao Jin, Tianli Yu, Hongling Wu, Shuo Lew, Wen Siang Chen, Xiong School of Physical and Mathematical Sciences Chemistry Covalent organic polymers Push-pull effects Covalent organic polymer (COP) thin film-based memristors have generated intensive research interest, but the studies are still in their infancy. Herein, by controlling the content of hydroxyl groups in the aldehyde monomer, Py-COP thin films with different electronic push-pull effects were fabricated bearing distinct memory performances, where the films were prepared by the solid-liquid interface method on the ITO substrates and further fabricated as memory devices with ITO/Py-COPs/Ag architectures. The Py-COP-1-based memory device only exhibited binary memory behavior with an ON/OFF ratio of 1:101.87. In contrast, the device based on Py-COP-2 demonstrated ternary memory behavior with an ON/OFF ratio of 1:100.6:103.1 and a ternary yield of 55%. The ternary memory mechanism of the ITO/Py-COP-2/Ag memory device is most likely due to the combination of the trapping of charge carriers and conductive filaments. Interestingly, the Py-COPs-based devices can successfully emulate the synaptic potentiation/depression behavior, clarifying the programmability of these devices in neuromorphic systems. These results suggest that the electronic properties of COPs can be precisely tuned at the molecular level, which provides a promising route for designing multi-level memory devices. This work was financially supported by the National Natural Science Foundation of China (Nos. 21972021 and 22111530111). Mr. Panke Zhou sincerely acknowledge the support of China Scholarship Council (No. 202206650013). 2024-05-07T05:04:12Z 2024-05-07T05:04:12Z 2024 Journal Article Zhou, P., Yu, H., Chee, M. Y., Zeng, T., Jin, T., Yu, H., Wu, S., Lew, W. S. & Chen, X. (2024). Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application. Chinese Chemical Letters, 35(5), 109279-. https://dx.doi.org/10.1016/j.cclet.2023.109279 1001-8417 https://hdl.handle.net/10356/175819 10.1016/j.cclet.2023.109279 2-s2.0-85188209693 5 35 109279 en Chinese Chemical Letters © 2024 Published by Elsevier B.V. on behalf of Chinese Chemical Society and Institute of Materia Medica, Chinese Academy of Medical Sciences. All rights reserved. |
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Chemistry Covalent organic polymers Push-pull effects |
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Chemistry Covalent organic polymers Push-pull effects Zhou, Panke Yu, Hong Chee, Mun Yin Zeng, Tao Jin, Tianli Yu, Hongling Wu, Shuo Lew, Wen Siang Chen, Xiong Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application |
| description |
Covalent organic polymer (COP) thin film-based memristors have generated intensive research interest, but the studies are still in their infancy. Herein, by controlling the content of hydroxyl groups in the aldehyde monomer, Py-COP thin films with different electronic push-pull effects were fabricated bearing distinct memory performances, where the films were prepared by the solid-liquid interface method on the ITO substrates and further fabricated as memory devices with ITO/Py-COPs/Ag architectures. The Py-COP-1-based memory device only exhibited binary memory behavior with an ON/OFF ratio of 1:101.87. In contrast, the device based on Py-COP-2 demonstrated ternary memory behavior with an ON/OFF ratio of 1:100.6:103.1 and a ternary yield of 55%. The ternary memory mechanism of the ITO/Py-COP-2/Ag memory device is most likely due to the combination of the trapping of charge carriers and conductive filaments. Interestingly, the Py-COPs-based devices can successfully emulate the synaptic potentiation/depression behavior, clarifying the programmability of these devices in neuromorphic systems. These results suggest that the electronic properties of COPs can be precisely tuned at the molecular level, which provides a promising route for designing multi-level memory devices. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Zhou, Panke Yu, Hong Chee, Mun Yin Zeng, Tao Jin, Tianli Yu, Hongling Wu, Shuo Lew, Wen Siang Chen, Xiong |
| format |
Article |
| author |
Zhou, Panke Yu, Hong Chee, Mun Yin Zeng, Tao Jin, Tianli Yu, Hongling Wu, Shuo Lew, Wen Siang Chen, Xiong |
| author_sort |
Zhou, Panke |
| title |
Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application |
| title_short |
Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application |
| title_full |
Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application |
| title_fullStr |
Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application |
| title_full_unstemmed |
Electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application |
| title_sort |
electron push-pull effects induced performance promotion in covalent organic polymer thin films-based memristor for neuromorphic application |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/175819 |
| _version_ |
1800916264653160448 |