Au‐Nanodots Embedded Self‐Rectifying Analog Charge Trap Memristor with Modified Bias Voltage Application Method for Stable Multi‐Bit Hardware‐Based Neural Network

Taegyun Park, Jihun Kim, Young Jae Kwon, Han Joon Kim, Seong Pil Yim, Dong Hoon Shin, Yeong Rok Kim, Hae Jin Kim, Cheol Seong Hwang
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Abstract

The self‐rectifying memristor with a bilayer of trap‐rich HfO2 and insulating Ta2O5 oxide layers is considered one of the most promising candidates for the memristive crossbar array due to its superior switching performance, scalability with 3D stacking, and low operating power. However, the output current variation due to the electron detrapping from trap states can cause the failure of critical operations in neuromorphic applications. This work suggests two solutions to mitigate the switching variations and insufficient data retention time by embedding gold nanodots and modifying the bias voltage application methods for read, write, and erase operations in the crossbar array. The switching mechanism is studied by varying the embedded position of the gold nanodots across the thickness direction of the bilayered oxides, which helped to optimize device performance further. Combining the two solutions into the proposed self‐rectifying memristor enables a single device to have the 7‐possible, stable states by preventing interstate overlap and securing the retention. Consequently, the hardware neural network consisting of self‐rectifying memristors with gold nanodots with the modified bias voltage application methods demonstrates a high inference accuracy of 93.1% in MNIST handwritten digit classification, comparable to the software‐based accuracy of 93.4%, benefiting from the enhanced multi‐state uniformity.

Abstract Image

金纳米点嵌入式自整流模拟电荷捕获晶闸管与用于稳定多位硬件神经网络的修正偏置电压应用方法
由富含阱的 HfO2 和绝缘的 Ta2O5 氧化层组成的双层自整流忆阻器因其优越的开关性能、三维堆叠的可扩展性和低工作功率而被认为是最有前途的忆阻器横条阵列候选器件之一。然而,由于电子从陷阱态脱离而导致的输出电流变化会导致神经形态应用中的关键操作失效。这项工作提出了两种解决方案,通过嵌入金纳米点和修改交叉条阵列中读取、写入和擦除操作的偏置电压应用方法,缓解开关变化和数据保留时间不足的问题。通过改变金纳米点在双层氧化物厚度方向上的嵌入位置来研究开关机制,这有助于进一步优化器件性能。将这两种解决方案结合到所提出的自校正忆阻器中,通过防止状态间重叠和确保保持,可使单个器件具有 7 种可能的稳定状态。因此,由自整流忆阻器和金纳米点组成的硬件神经网络采用改进的偏置电压应用方法,在MNIST手写数字分类中实现了93.1%的高推理准确率,与基于软件的93.4%的准确率相当,这得益于增强的多态均匀性。
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