Simulation and Analysis of Hybrid Ultra Dense Memory Cell by Using Single Electron Transistor

2014 International Conference on Electronic Systems, Signal Processing and Computing Technologies Pub Date : 2014-01-09 DOI:10.1109/ICESC.2014.62

J. R. Chaudhari, D. Gautam

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引用次数: 3

Abstract

In VLSI Technology, Integration Density of memory requirements have reached in tera byte. The basic element to design any type of memory array is memory cell. To design a memory array, selective read and write memory cells are most important. The most promising application of single electronic devices is the Single Electron Memory cell. Here, we propose to design a memory cell using single electron transistor. The working depends upon the coulomb blockade phenomenon, in which electrons are tunneled one by one through the channel. Basic single electron cell are utilized throughout the work as electron trap. The hybrid electron trap memory is directly utilized to design a random access memory array. Information storage is due to the presence or absence of single electron at island. The paper gives a new dimension to make a different memory cell by using a hybrid multi island junction. The operation of proposed circuits are verified in Monte Carlo Simulator Tool SIMON2 (Simulation of nanoelectronics device) which is a simulator for single electron tunnel circuits and devices. The stability diagram is verified by the functioning of the circuits.

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基于单电子晶体管的混合超密存储单元仿真与分析

在VLSI技术中，存储器的集成密度要求已达到兆兆字节。设计任何类型的存储阵列的基本元素是存储单元。在设计存储阵列时，选择读写存储单元是最重要的。单电子器件最有前途的应用是单电子存储单元。在此，我们建议设计一个使用单电子晶体管的存储单元。工作依赖于库仑阻塞现象，在这种现象中，电子一个接一个地穿过通道。在整个工作过程中，基本的单电子电池被用作电子陷阱。混合电子阱存储器直接用于随机存取存储器阵列的设计。信息存储是由于孤岛上单个电子的存在或不存在。本文提出了利用混合多岛结制造不同存储单元的新思路。在蒙特卡罗仿真工具SIMON2(模拟纳米电子器件)中验证了所提出电路的运行，SIMON2是一个单电子隧道电路和器件的模拟器。稳定性图通过电路的功能得到验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2014 International Conference on Electronic Systems, Signal Processing and Computing Technologies

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