Key Laboratory of Microelectronic Devices and Integrated Technology, Institute of Microelectronics, Chinese Academy of Sciences, Beijing, 100029, China.
University of Chinese Academy of Sciences, Beijing, 100049, China.
Adv Mater. 2020 Nov;32(47):e2003018. doi: 10.1002/adma.202003018. Epub 2020 Oct 20.
Spiking neural networks (SNNs) sharing large similarity with biological nervous systems are promising to process spatiotemporal information and can provide highly time- and energy-efficient computational paradigms for the Internet-of-Things and edge computing. Nonvolatile electrolyte-gated transistors (EGTs) provide prominent analog switching performance, the most critical feature of synaptic element, and have been recently demonstrated as a promising synaptic device. However, high performance, large-scale EGT arrays, and EGT application for spatiotemporal information processing in an SNN are yet to be demonstrated. Here, an oxide-based EGT employing amorphous Nb O and Li SiO is introduced as the channel and electrolyte gate materials, respectively, and integrated into a 32 × 32 EGT array. The engineered EGTs show a quasi-linear update, good endurance (10 ) and retention, a high switching speed of 100 ns, ultralow readout conductance (<100 nS), and ultralow areal switching energy density (20 fJ µm ). The prominent analog switching performance is leveraged for hardware implementation of an SNN with the capability of spatiotemporal information processing, where spike sequences with different timings are able to be efficiently learned and recognized by the EGT array. Finally, this EGT-based spatiotemporal information processing is deployed to detect moving orientation in a tactile sensing system. These results provide an insight into oxide-based EGT devices for energy-efficient neuromorphic computing to support edge application.
尖峰神经网络 (SNN) 与生物神经系统具有很大的相似性,有望处理时空信息,并为物联网和边缘计算提供高度节省时间和能源的计算范例。非易失性电解质门控晶体管 (EGT) 提供了突出的模拟开关性能,这是突触元件的最关键特征,最近已被证明是一种很有前途的突触器件。然而,高性能、大规模的 EGT 阵列以及 EGT 在 SNN 中用于时空信息处理的应用仍有待证明。在这里,采用基于氧化物的 EGT,分别使用非晶态 NbO 和 LiSiO 作为沟道和电解质栅材料,并集成到一个 32×32 的 EGT 阵列中。所设计的 EGT 表现出准线性更新、良好的耐久性(10 次循环)和保持力、高达 100ns 的高速开关速度、超低读取电导(<100nS)和超低单位面积开关能量密度(20fJ µm )。突出的模拟开关性能被用于硬件实现具有时空信息处理能力的 SNN,其中具有不同定时的尖峰序列可以被 EGT 阵列高效地学习和识别。最后,该基于 EGT 的时空信息处理被部署用于检测触觉传感系统中的运动方向。这些结果为基于氧化物的 EGT 器件用于节能神经形态计算以支持边缘应用提供了深入的了解。
