通过极性控制增强 CNTVT:SVS 共聚物上的阴离子相互作用，从而改善神经形态计算的非易失性特性

IF 8.7 1区化学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

ACS Materials Letters Pub Date : 2024-05-14 DOI:10.1021/acsmaterialslett.4c00087

Donghwa Lee, Landep Ayuningtias, Jinwoo Hwang, Junho Sung, Joonhee Kang*, Yun-Hi Kim* and Eunho Lee*,

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引用次数: 0

摘要

模拟生物功能的突触器件因其低功耗特性而受到神经形态计算的关注。然而，在电解质门控晶体管（EGTs）中实现长期可塑性（LTP）具有挑战性，因为当去除栅极电压时，电解质/沟道的电双层（EDL）就会消失。在这项研究中，我们通过调整骨干的极性制造出了基于 CNTVT 的 EGT。这一过程包括通过调整 DPP-CNTVT 的比例来改善骨架的极性。此外，它还能促进 DEME-TFSI 中的 TFSI 阴离子在电解质/通道界面上的结合。基于 CNTVT 的 EGT 成功实现了 LTP，并表现出基本的突触特性，包括成对脉冲促进（PPF）和高通滤波器。此外，在控制骨干极性的情况下，基于长期延时/抑制（LTP/LTD）驱动 MNIST 手写数字的结果从 50.18% 提高到 93.28%。这些发现为利用最先进的神经建模技术的突触设备提供了一种简单的架构设计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Enhanced Anion Interaction by Polarity Control on CNTVT:SVS Copolymers for Improving Nonvolatile Characteristics in Neuromorphic Computing

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Enhanced Anion Interaction by Polarity Control on CNTVT:SVS Copolymers for Improving Nonvolatile Characteristics in Neuromorphic Computing

Synaptic devices that simulate biological functions are of interest in neuromorphic computing, because of their low power consumption characteristics. However, achieving long-term plasticity (LTP) in electrolyte-gated transistors (EGTs) is challenging, because the electric double layer (EDL) of the electrolyte/channel disappears when the gate electrode voltage is removed. In this study, we fabricated a CNTVT-based EGTs by adjusting the polarity of the backbone. This process involves improving the polarity of the backbone by adjusting the DPP-CNTVT ratio. Furthermore, it facilitates increased binding of TFSI anions in DEME-TFSI at the electrolyte/channel interface. The CNTVT-based EGTs successfully achieved LTP and exhibited essential synaptic properties, including paired-pulse facilitation (PPF) and a high-pass filter. Furthermore, the results of driving MNIST handwritten digits based on long-term potentiation/depression (LTP/LTD) with controlled backbone polarity improved from 50.18% to 93.28%. These findings offer a simple architectural design for synaptic devices that leverage state-of-the-art neural modeling techniques.

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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.