Accurate TEM measurements of the injection distances in nanocrystal based memories

Ion Implantation Technology. 2002. Proceedings of the 14th International Conference on Pub Date : 1900-01-01 DOI:10.1109/IIT.2002.1258089

A. Carrada, B. Assayag, C. Bonafos, A. Claverie, P. Normand, D. Tsoukalas

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Abstract

Silicon nanocrystals buried in a thin oxide can be used as charge storage elements and be integrated in standard CMOS technology to fabricate new non-volatile memory devices. The control of the distances between the nanocrystals layer and the two electrodes of the MOS determines the final characteristics of the device (write-erase and retention times). This 2D arrays of ncs can be elaborated by ion implantation of Si at low energy. In this paper, we compare two transmission electron microscopy methods that can be used to extract such distances in 10 nm-thick SiO2 layers implanted with Si at low energy. We demonstrate by using image simulations that conventional electron microscopy under out-of-Bragg and strongly underfocussed conditions is the fastest and most efficient technique to be used for routine measurements at subnanometer resolution. Our results show that the injection distance in such devices can be precisely tuned from 5 to 8 nm by adjusting the Si implantation energy from 0.65 keV to 2 keV.

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纳米晶基记忆体中注射距离的精确透射电镜测量

埋在薄氧化物中的硅纳米晶体可以用作电荷存储元件，并集成到标准的CMOS技术中，以制造新的非易失性存储器件。纳米晶体层与MOS两个电极之间距离的控制决定了器件的最终特性(写入擦除和保留时间)。这种二维纳米阵列可以通过低能量的Si离子注入来制备。在本文中，我们比较了两种透射电子显微镜方法，这两种方法可用于在低能量注入Si的10 nm厚SiO2层中提取这样的距离。我们通过使用图像模拟证明，在out- bragg和强烈欠聚焦条件下的传统电子显微镜是用于亚纳米分辨率常规测量的最快和最有效的技术。结果表明，通过将Si注入能量从0.65 keV调整到2 keV，可以精确地将器件中的注入距离从5 nm调整到8 nm。

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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Ion Implantation Technology. 2002. Proceedings of the 14th International Conference on

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