C. Wu, H. Lue, T. Hsu, C. Hsieh, Wei-Chen Chen, P. Du, C. Chiu, Chih-Yuan Lu
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引用次数: 12
摘要
详细讨论了单栅垂直通道(SGVC)三维NAND结构的器件特性。SGVC最重要的特点是存储单元是3D平面通道器件,不同于更常用的栅极全能(GAA)通心粉单元。通过各种器件优化,我们成功地生产了优异的电池初始性能和每个存储电池超过10V的峰值P/E窗口。与GAA电池形成鲜明对比的是,SGVC平面电池具有优越的层对层器件均匀性,可以承受非理想的垂直蚀刻。讨论了MLC和TLC应用程序中的内存窗口管理。研究发现,主要的干扰因素来自于局域间的干扰。在无结的三维NAND中,所选栅极与相邻栅极之间的通道电位相互作用是产生WL干扰的根本原因。随机晶界陷阱效应进一步恶化了WL干扰。研究发现,传统FG NAND中常用的WL迭代算法也适用于我们的SGVC 3D NAND,可以为MLC和TLC应用提供非常紧密的Vt分布。
Device Characteristics of Single-Gate Vertical Channel (SGVC) 3D NAND Flash Architecture
Device characteristics of single-gate vertical channel (SGVC) 3D NAND architecture are discussed in detail. The most important feature of SGVC is that the memory cell is a flat-channel device in 3D, different from the more often used gate-all-around (GAA) macaroni cell. Through various device optimizations, we have successfully produced excellent cell initial performances and more than 10V peak P/E window for each memory cell. In sharp contrast to the GAA cell, the SGVC flat cell naturally has superior layer-to-layer device uniformity that tolerates non-ideal vertical etching. Memory window managements in MLC and TLC applications are discussed. It is found that the major interference factor comes from the WL to WL interference. The root cause of WL interference is identified to be the channel potential interaction between the selected gate and neighbor WL in a junction-free 3D NAND. Random grain boundary trap effect further deteriorates the WL interference. It is found that the commonly adopted WL iterating algorithms in conventional FG NAND is also suitable for our SGVC 3D NAND to provide very tight Vt distribution for MLC and TLC applications.
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