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Flexible In–Ga–Zn–N–O synaptic transistors for ultralow-power neuromorphic computing and EEG-based brain–computer interfaces

Shuangqing Fan, Enxiu Wu, Minghui Cao, Ting Xu, Tong Liu, Lijun Yang, Jie Su, Jing Liu

2023Materials Horizons22 citationsDOI

Abstract

Designing low-power and flexible artificial neural devices with artificial neural networks is a promising avenue for creating brain-computer interfaces (BCIs). Herein, we report the development of flexible In-Ga-Zn-N-O synaptic transistors (FISTs) that can simulate essential and advanced biological neural functions. These FISTs are optimized to achieve ultra-low power consumption under a super-low or even zero channel bias, making them suitable for wearable BCI applications. The effective tunability of synaptic behaviors promotes the realization of associative and non-associative learning, facilitating Covid-19 chest CT edge detection. Importantly, FISTs exhibit high tolerance to long-term exposure under an ambient environment and bending deformation, indicating their suitability for wearable BCI systems. We demonstrate that an array of FISTs can classify vision-evoked EEG signals with up to ∼87.9% and 94.8% recognition accuracy for EMNIST-Digits and MindBigdata, respectively. Thus, FISTs have enormous potential to significantly impact the development of various BCI techniques.

Topics & Concepts

Brain–computer interfaceNeuromorphic engineeringComputer scienceWearable computerElectroencephalographyArtificial neural networkTransistorArtificial intelligencePattern recognition (psychology)NeuroscienceEmbedded systemElectrical engineeringVoltageEngineeringPsychologyAdvanced Memory and Neural ComputingTransition Metal Oxide NanomaterialsCCD and CMOS Imaging Sensors
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