非易失性MRAM位单元的设计

Nikita Gupta, Pragati Thakur, S. Dubey, A. Islam
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引用次数: 0

摘要

尽管摩尔定律是迄今为止最受追捧的原理;在目前的情况下,将其应用于传统的MOS结构已经变得很麻烦。亚阈值泄漏电流的显著增加以及栅极-介电泄漏、栅极-感应漏极(GIDL)等缺点是限制MOS器件缩放的主要因素。因此,研究人员需要新颖的想法和机械化。在众多最新的表面器件中,碳纳米管场效应晶体管(CNFET)由于其令人羡慕的电学、物理和机械特性,正成为mosfet的有希望的替代品。本文提出了一种基于电路的技术来减少MTJ存储单元读写操作余量等对设计指标的不利影响。研究了工艺、电压和温度(PVT)变化的影响。这项研究是基于蒙特卡罗模拟在HSPICE环境中,使用斯坦福CNFET模型。本文提出了基于功率门控技术的2- cnfet, 1-MTJ的STT-MRAM位单元,以提高其性能指标。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design of nonvolatile MRAM bitcell
Although Moore's law has been the most pursued principle since ever; it has become troublesome to apply that on the traditional MOS structures in today's scenario. Striking increment in the subthreshold leakage current, and various other disadvantages like gate-dielectric leakage gate-induced drain leakage (GIDL) are the major factors which limit the scaling of the MOS devices. And so, researchers are in need of novel ideas and mechanizations. Of so many of the lately surfacing devices, Carbon Nanotube Field Effect Transistor (CNFET) is becoming the hopeful alternative of MOSFETs, owing to its enviable properties of electrical, physical and mechanical factors. In this paper, a circuit based technique to lessen the unfavorable effects on the design metrics such as margin for write and read operation of MTJ memory cell is proposed. The effects of process, voltage and temperature (PVT) variations are investigated. The study is based on Monte Carlo simulations in a HSPICE environment, using a Stanford CNFET model. In this work, 2-CNFETs, 1-MTJ based STT-MRAM bit cell based on power gating technique is suggested to improve its performance metrics.
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