Achieving Sub-ns switching of STT-MRAM for future embedded LLC applications through improvement of nucleation and propagation switching mechanisms

2016 IEEE Symposium on VLSI Technology Pub Date : 2016-06-14 DOI:10.1109/VLSIT.2016.7573362

G. Jan, L. Thomas, S. Le, Yuan-Jen Lee, Huanlong Liu, Jian Zhu, J. Iwata-Harms, Sahil J. Patel, R. Tong, S. Serrano-Guisan, D. Shen, R. He, J. Haq, J. Teng, V. Lam, R. Annapragada, Yu-Jen Wang, T. Zhong, T. Torng, P. Wang

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引用次数: 30

Abstract

We present recent advances in writing speed of pSTT_MRAM which demonstrate its potential as a candidate for replacement of LCC cache for advanced technology nodes as well as applications where non-volatility may be needed. In this paper we explore the feasibility of sub-ns switching of devices and their characterization using comprehensive time resolved electrical measurement of the reversal mechanism. We show that the switching mechanism can be described as a simple nucleation followed by propagation model that can be characterized statistically. We further demonstrate that after optimization of the Magnetic Tunnel Junction (MTJ) stack, single devices can be switched reliably using write pulse length down to 750ps while preserving functionality and data retention @ 125°C. Results of the integration at array level on an 8MB test vehicle are also presented allowing full array writing using 3ns pulses without ECC and demonstrated data retention of 10 years (1ppm) at 125°C.

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通过改进成核和传播切换机制，实现STT-MRAM在未来嵌入式LLC应用中的Sub-ns切换

我们介绍了pSTT_MRAM写入速度的最新进展，这表明它有潜力替代先进技术节点的LCC缓存，以及可能需要非易失性的应用。在本文中，我们探索了亚ns开关器件的可行性，并利用反转机制的综合时间分辨电测量来表征它们。我们表明，开关机制可以描述为一个简单的成核，然后是一个可以统计表征的传播模型。我们进一步证明，在优化磁隧道结(MTJ)堆栈后，可以使用写脉冲长度降至750ps的情况下可靠地切换单个器件，同时在125°C时保持功能和数据保留。在8MB测试车上，阵列级集成的结果也被展示出来，允许使用3ns脉冲无ECC的全阵列写入，并证明了在125°C下数据保留10年(1ppm)。

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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2016 IEEE Symposium on VLSI Technology

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