无结无电容DRAM的架构优化提高保留率

2018 4th IEEE International Conference on Emerging Electronics (ICEE) Pub Date : 2018-12-01 DOI:10.1109/icee44586.2018.8937914

Md. Hasan Raza Ansari, A. Kranti

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摘要

研究结果表明，器件结构对提高无接点无电容动态随机存取存储器(1T-DRAM)的保持时间(RT)具有重要意义。DRAM的传导区和存储区通过氧化物分离。顶部(n型)区域用于传导，背面(p型)区域用于电荷存储。存储电荷所需的电位阱也可以通过金属氧化物半导体(MOS)效应实现。当栅极长度为200 nm时，最大RT为$\sim 3.8\mathrm{s}$;当栅极长度为$85^{\circ}\mathrm{C}$时，最大RT为$\sim 1$ ms，最大RT降至$ 10 nm。研究了缩小总长度和总厚度的意义。通过带对带隧道(BTBT)进行写“1”操作(产生空穴)所需的偏置可以缩放到0.5 V，栅极长度为25 nm, RT为$ $ sim 220$ ms，温度为$85^{\circ}\ mathm {C}$。

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Retention Enhancement through Architecture Optimization in Junctionless Capacitorless DRAM

The work shows the significance of device architecture to enhance the Retention Time (RT) of Junctionless Capacitorless Dynamic Random Access Memory (1T-DRAM). The conduction and storage regions of the DRAM are segregated through an oxide. The top (n-type) region is utilized for conduction while back region (p-type) for charge storage. A potential well, required to store charges, is also achieved through a Metal-Oxide-Semiconductor (MOS) effect. A maximum RT of $\sim 3.8\mathrm{s}$ is achieved with gate length of 200 nm and is scaled down to 10 nm with RT of $\sim 1$ ms at $85^{\circ}\mathrm{C}$. The significance of scaling down total length and thickness is examined. It is possible to scale the bias required to perform Write “1” operation (generation of holes) through Band-to-Band-Tunneling (BTBT) to 0.5 V for gate length of 25 nm with RT of $\sim 220$ ms at $85^{\circ}\mathrm{C}$.

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2018 4th IEEE International Conference on Emerging Electronics (ICEE)

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