A Study of Blocking and Tunnel Oxide Engineering on Double-Trapping (DT) BE-SONOS Performance

2015 IEEE International Memory Workshop (IMW) Pub Date : 2015-05-17 DOI:10.1109/IMW.2015.7150273

R. Lo, P. Du, T. Hsu, C. Wu, Jung-Yi Guo, C. Cheng, H. Lue, Y. Shih, T. Hou, K. Hsieh, Chih-Yuan Lu

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引用次数: 1

Abstract

Double-trapping bandgap engineered SONOS (DT BE-SONOS) [1] was proposed to provide both fast erase speed and deep erase by means of a second nitride trapping layer and an additional blocking oxide on top of BE-SONOS. Although this provides excellent erase performance but the additional layers increase the EOT and subsequently the erase voltage, thus it is desirable to minimize their impact. This work investigates exhaustively the effect of thinning down the blocking layers. Since the ISPP and high temperature retention charge loss are mainly dominated by the ONO thickness of BE-SONOS below the blocking layers, reducing the blocking layer thickness has only minor impact on ISPP and retention. Moreover, erase saturation is determined by the dynamic balance of channel hole injection and gate electron injection. Experimental data show that reducing the thickness of the oxide between two trapping layers has little impact on erase saturation once the gate injected electrons are efficiently suppressed by the top most oxide. We have also investigated retention improvement by various oxides. By using HQ-SiO2 to replace the top tunnel ONO the trapped electron out-tunneling is reduced. Thus retention may be improved without increasing the effective oxide thickness.

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双捕集(DT) BE-SONOS性能的阻塞和隧道氧化工程研究

提出了双捕获带隙工程SONOS (DT BE-SONOS)[1]，通过在BE-SONOS上添加第二个氮化物捕获层和额外的阻塞氧化物，提供快速擦除速度和深度擦除。虽然这提供了出色的擦除性能，但额外的层增加了EOT，随后增加了擦除电压，因此希望尽量减少它们的影响。这项工作详尽地研究了减薄阻挡层的效果。由于ISPP和高温保留电荷损失主要由阻挡层以下BE-SONOS的ONO厚度决定，因此减小阻挡层厚度对ISPP和保留的影响较小。擦除饱和由通道空穴注入和栅极电子注入的动态平衡决定。实验数据表明，一旦栅极注入的电子被最顶层的氧化物有效抑制，减小两层捕获层之间的氧化物厚度对擦除饱和的影响很小。我们还研究了各种氧化物对保留率的改善。用HQ-SiO2代替顶部隧穿ONO，减少了捕获电子的出隧穿。因此，可以在不增加有效氧化物厚度的情况下改善保留。

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 International Memory Workshop (IMW)

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