Organic Solid-State Electrolyte Synaptic Transistors with Photoinduced Thiol-Ene Cross-linked Polymer Electrolytes for Deep Neural Networks.

IF 8.7 1区化学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY ACS Materials Letters Pub Date : 2025-01-23 eCollection Date: 2025-02-03 DOI:10.1021/acsmaterialslett.4c02511

Qun-Gao Chen, Wei-Ting Liao, Rou-Yi Li, Ignacio Sanjuán, Ning-Cian Hsiao, Chan-Tat Ng, Ting-Ting Chang, Antonio Guerrero, Chu-Chen Chueh, Wen-Ya Lee

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Abstract

In this work, we describe a solid-state polymer electrolyte (SPE)-based electrolyte-gated organic field-effect transistors (EGOFETs) consisting of a thiol-ene-assisted photo-cross-linked nitrile butadiene rubber (NBR) network embedded with lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) electrolyte. The photocurable SPE film can be patterned with different dimensions by photolithography and exhibits excellent electronic properties and crucial synaptic behavior. The photocurable NBR/LiTFSI EGOFET exhibits a high transconductance of 11.9 mS and a high on/off ratio of 10⁵ at a scan rate of 40 mV/s. Due to the strongly polarized nature of the photo-cross-linked NBR network and Li-ion diffusion, the NBR/LiTFSI device exhibits a significant current hysteresis, enabling synaptic-like learning and memory behavior. The NBR/LiTFSI device demonstrates a DNN of 91.9% handwritten digit recognition accuracy. This work demonstrates the potential of the solid-state NBR/LiTFSI EGOFET in creating highly efficient and low-energy neuromorphic devices.

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用于深度神经网络的有机固态电解质突触晶体管与光诱导巯基烯交联聚合物电解质。

在这项工作中，我们描述了一种基于固态聚合物电解质（SPE）的电解质门控有机场效应晶体管（egofet），该晶体管由巯基辅助光交联丁腈橡胶（NBR）网络嵌入双（三氟甲磺酰基）亚胺锂（LiTFSI）电解质组成。可光固化的SPE薄膜可以通过光刻技术制作出不同尺寸的图案，并具有优异的电子性能和关键的突触行为。光固化NBR/LiTFSI EGOFET在扫描速率为40 mV/s时具有11.9 mS的高跨导和105的高通/关比。由于光交联NBR网络和锂离子扩散的强极化性质，NBR/LiTFSI器件表现出明显的电流滞后，从而实现类似突触的学习和记忆行为。NBR/LiTFSI器件的DNN手写数字识别准确率为91.9%。这项工作证明了固态NBR/LiTFSI EGOFET在创造高效低能神经形态器件方面的潜力。

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来源期刊

ACS Materials Letters MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

14.60

自引率

3.50%

发文量

261

期刊介绍： ACS Materials Letters is a journal that publishes high-quality and urgent papers at the forefront of fundamental and applied research in the field of materials science. It aims to bridge the gap between materials and other disciplines such as chemistry, engineering, and biology. The journal encourages multidisciplinary and innovative research that addresses global challenges. Papers submitted to ACS Materials Letters should clearly demonstrate the need for rapid disclosure of key results. The journal is interested in various areas including the design, synthesis, characterization, and evaluation of emerging materials, understanding the relationships between structure, property, and performance, as well as developing materials for applications in energy, environment, biomedical, electronics, and catalysis. The journal has a 2-year impact factor of 11.4 and is dedicated to publishing transformative materials research with fast processing times. The editors and staff of ACS Materials Letters actively participate in major scientific conferences and engage closely with readers and authors. The journal also maintains an active presence on social media to provide authors with greater visibility.

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