新一代3D NAND高漏极电流和可行扰动的p通道FE NAND的提出

Song-Hyeon Kuk, Jaehoon Han, Bong-Ho Kim, Junpyo Kim, Sang-Hyeon Kim
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引用次数: 0

摘要

最近,由于单元和堆叠层的物理限制超过1000,下一代3D NAND闪存对更高漏极电流和可扩展栅极堆栈厚度的需求出现了。虽然n沟道铁电场效应晶体管(n-FEFET)的研究已经克服了这一限制,但由于在程序和读取过程中寄生电子捕获,它带来了关键的可靠性问题,这降低了保留性,耐用性,并引起干扰和电池失效。我们展示了2位多电平单元(MLC) p通道ffet (p- ffet)用于(嵌入式)NAND闪存应用的可行性。p - ffet本质上具有比n- ffet更高的导通电流。这是由于缺乏空穴捕获,导致铁电电荷在通道处增强。其他特性(保持、扰动等)也表明,当p- ffet用于NAND闪存时,它的电特性显著改善,而不是用于nffet。最后,我们提出了pFENAND器件的工程化策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Proposal of P-Channel FE NAND with High Drain Current and Feasible Disturbance for Next Generation 3D NAND
Recently the demand for higher drain current and scalable gate stack thickness arises for next-generation 3D NAND flash, due to the physical limit of cells and stacked layers over 1,000. While the N-channel ferroelectric field-effect-transistor (n-FEFET) has been studied to overcome the limit, it brings the critical reliability issue due to parasitic electron trapping during the program and read, which degrades retention, endurance and induces disturbance and cell failure. We show the feasibility of 2-bit multi-level-cell (MLC) p-channel FEFET (p-FEFET) for (embedded) NAND flash memory application. P-FEFET intrinsically has higher on-current than n-FEFET. It is due to the absence of hole trapping, which leads to ferroelectric charge boosting at the channel. Other properties (retention, disturbance, etc) also show that p-FEFET has remarkably improved electrical characteristics when it is targeted for NAND flash, rather than nFEFET. Finally, we propose a strategy for engineering the pFENAND device.
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