Modulating Alkyl Groups in Copolymer to Control Ion Transport in Electrolyte-Gated Organic Transistors for Neuromorphic Computing

Junho Sung, Minji Kim, Sein Chung, Yongchan Jang, Soyoung Kim, Min-Seok Kang, Hee-Young Lee, Joonhee Kang, Donghwa Lee, Wonho Lee, Eunho Lee
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Abstract

Electrolyte-gated organic synaptic transistors (EGOSTs) have shed light on their potential in bioelectronics and neuromorphic computing. Numerous research have been studied to modulate their electrochemical doping performance and formulate a simple approach to control iontronics through the side-chain modulations; however, the effects of alkyl groups as side moieties have not been studied in detail on EGOSTs. Herein, the structural and electrical properties of conjugated polymers are systematically controlled through copolymerization with two different-alkyl group-derived monomers for enhancing the nonvolatile characteristics of EGOSTs. The relationships between crystal orientation and electrochemical doping states of conjugated copolymers, which varied with the different copolymerization ratios, are revealed. Also, the behavior of biological synapses, including paired-pulse facilitation, spike timing-dependent plasticity, and long-term potentiation/depression, are successfully simulated. In this study, new avenues are opened for the implementation of neuromorphic devices through side-chain engineering by showing that the alkyl chain modulates the doping performance.

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调节共聚物中的烷基,控制用于神经形态计算的电解质门控有机晶体管中的离子传输
电解质门控有机突触晶体管(EGOSTs)揭示了其在生物电子学和神经形态计算方面的潜力。为了调节其电化学掺杂性能并制定一种通过侧链调节来控制离子电子学的简单方法,人们进行了大量研究;然而,烷基作为侧基对 EGOST 的影响还没有得到详细研究。在本文中,通过与两种不同的烷基单体共聚,系统地控制了共轭聚合物的结构和电学特性,从而增强了 EGOST 的不挥发性。研究揭示了共轭共聚物的晶体取向与电化学掺杂状态之间的关系,它们随不同的共聚比例而变化。此外,还成功模拟了生物突触的行为,包括成对脉冲促进、尖峰计时可塑性和长期延时/抑制。这项研究表明,烷基链可调节掺杂性能,从而为通过侧链工程实现神经形态器件开辟了新途径。
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