磁性存储器的量子传感计量学

Vicent J. Borràs, Robert Carpenter, Liza Žaper, Siddharth Rao, Sebastien Couet, Mathieu Munsch, Patrick Maletinsky, Peter Rickhaus
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引用次数: 0

摘要

磁性随机存取存储器(MRAM)是一种领先的新兴存储器技术,有望取代目前的非易失性存储器技术(如 eFlash)。然而,在这一技术发展阶段,控制和改进器件特性的分布成为新应用的关键因素。在这里,我们介绍了一种非接触式计量技术,利用扫描非接触式磁强计(SNVM)来研究单个位级的 MRAM 性能。我们展示了单个 60 nm 大小位的磁反转特性,以提取关键的磁特性、热稳定性和开关统计量,从而衡量位与位之间的一致性。我们在图案形成后立即对两个不同的位蚀刻过程进行了基准测试,从而展示了我们方法的性能。与垂直磁光克尔效应等集合平均法相比,我们的方法可以识别出似乎与阵列边缘相关的分布外比特(尾比特),从而对尾比特进行故障分析。我们的研究结果凸显了 MRAM 器件的纳米级量子传感在加工生产线早期筛选方面的潜力,为半导体行业未来采用这种纳米级表征工具铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A quantum sensing metrology for magnetic memories

A quantum sensing metrology for magnetic memories
Magnetic random access memory (MRAM) is a leading emergent memory technology that is poised to replace current non-volatile memory technologies such as eFlash. However, controlling and improving distributions of device properties becomes a key enabler of new applications at this stage of technology development. Here, we introduce a non-contact metrology technique deploying scanning NV magnetometry (SNVM) to investigate MRAM performance at the individual bit level. We demonstrate magnetic reversal characterization in individual, <60 nm-sized bits, to extract key magnetic properties, thermal stability, and switching statistics, and thereby gauge bit-to-bit uniformity. We showcase the performance of our method by benchmarking two distinct bit etching processes immediately after pattern formation. In contrast to ensemble averaging methods such as perpendicular magneto-optical Kerr effect, we show that it is possible to identify out of distribution (tail-bits) bits that seem associated to the edges of the array, enabling failure analysis of tail bits. Our findings highlight the potential of nanoscale quantum sensing of MRAM devices for early-stage screening in the processing line, paving the way for future incorporation of this nanoscale characterization tool in the semiconductor industry.
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