Read disturbance issue for nanoscale STT-MRAM

2015 IEEE Non-Volatile Memory System and Applications Symposium (NVMSA) Pub Date : 2015-10-29 DOI:10.1109/NVMSA.2015.7304372

Yi Ran, W. Kang, Youguang Zhang, Jacques-Olivier Klein, Weisheng Zhao

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引用次数: 10

Abstract

Spin transfer torque magnetic random access memory (STT-MRAM) has been widely considered as one of the most promising candidates for the next-generation nonvolatile memory technologies, thanks to its attractive features, including high density, high speed, low power and high endurance etc. However, our investigation demonstrates that read disturbance may become a big reliability issue of STT-MRAM, since read and write currents share the same path. As technology scales down to nanoscale nodes, this read disturbance issue becomes more serious and may turn into be a critical reliability barrier for STT-MRAM commercialization, because the difference between the read and write currents decreases. In this paper, we propose a circuit to detect the read disturbance by exploiting its typical features, i.e., (a) the resistance (read current) of the memory cell will have a sudden change if read disturbance occurs; (b) only one-direction of read disturbance can occur during normal read operations. Based on the detection results, the correct data can be restored back into the memory cells after read disturbance or system-level algorithms can be employed to correct the read disturbance fault.

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纳米级STT-MRAM的读取干扰问题

自旋转移转矩磁随机存取存储器(STT-MRAM)由于具有高密度、高速、低功耗和高耐用性等优点，已被广泛认为是下一代非易失性存储器技术中最有前途的候选技术之一。然而，我们的研究表明，读干扰可能成为STT-MRAM的一个大的可靠性问题，因为读和写电流共享同一路径。随着技术规模缩小到纳米级节点，读取干扰问题变得更加严重，并可能成为STT-MRAM商业化的关键可靠性障碍，因为读写电流之间的差异减小了。在本文中，我们提出了一种利用读干扰的典型特征来检测读干扰的电路，即:(a)当读干扰发生时，存储单元的电阻(读电流)会发生突然变化;(b)在正常的读操作中，只能发生一个方向的读干扰。根据检测结果，可以在读取干扰后将正确的数据恢复到存储单元中，也可以采用系统级算法来纠正读取干扰故障。

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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2015 IEEE Non-Volatile Memory System and Applications Symposium (NVMSA)

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