Fluorinated Self-Assembled Monolayer Ion Receptors for Retentive Analog Synaptic Behavior.

Numerous studies have highlighted ionic transistors as a promising candidate for retentive artificial synapses in analog neuromorphic computing, owing to their exceptional characteristics of analog signal modulation and low energy consumption. However, the self-discharge of ions at the channel-electrolyte interface limits their retention characteristics. Therefore, it is crucial to control the ion discharge kinetics by engineering interfacial electrostatic interactions. By precisely tuning the ion discharging time through interface design, ionic transistors can achieve the stable, long-lasting charge retention required for retentive artificial synapses in training acceleration and inference. Herein, a principled approach is proposed to enhance ion interactions by introducing a fluorinated self-assembled monolayer (F-SAM), Heneicosafluorododecyl phosphonic acid (F21-DDPA), as an ion receptor in electrolyte-gated transistors (EGTs). This device induces strong ion-dipole interactions between lithium ions and negatively charged F21-DDPA at the channel/electrolyte interface. Incorporating F21-DDPA allows the lithium ions to be trapped at the interface, enabling the EGTs to maintain near-linearly tunable multimodal conductance states. Additionally, through chemical analysis and first-principles density functional theory calculations, F21-DDPA can facilitate sequential lithium ion trapping at the interface by ion-dipole forces. This approach provides a fundamental solution to understanding ion dynamics at the interface and resolving the issues associated with ionic transistors for applications in artificial synapses.