Reliability study of MANOS with and without a SiO2 buffer layer and BE-MANOS charge-trapping NAND flash devices

C.W. Liao, S. Lai, H. Lue, Ming-Jui Yang, C. Shen, Y. Lue, Yu-Fong Huang, J. Hsieh, Szu-Yu Wang, G. Luo, C. Chien, K. Hsieh, Rich Liu, Chih-Yuan Lu
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引用次数: 6

Abstract

The reliability of MANOS devices with an oxide buffer layer (MAONOS) in between SiN trapping layer and high-K Al2O3 top dielectric is extensively studied. We conclude that the primary function of high-K Al2O3 is to suppress the gate electron injection during erase instead of increasing the P/E speed. As a result, inserting a buffer oxide only changes EOT but does not change the P/E mechanisms. On the other hand, the buffer oxide can greatly improve data retention by suppressing leakage through Al2O3. However, owing to the slow erase performances with a thick bottom oxide, both MANOS and MAONOS erase slowly and very high erase voltages must be used. Also, both MANOS and MAONOS devices show very fast endurance degradation below P/E≪10, which is inherent due to electron de-trapping mechanism. Moreover, the large erase voltage also causes severe degradation of tunnel oxide after many P/E cycling. To get both speed and reliability performances, it is necessary to introduce bandgap engineered tunneling barrier (BE-MANOS) to solve the fundamental problems of MANOS.
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有和没有SiO2缓冲层的MANOS和BE-MANOS电荷捕获NAND闪存器件的可靠性研究
本文广泛研究了在SiN捕获层和高k Al2O3顶部电介质之间添加氧化物缓冲层(MAONOS)的MANOS器件的可靠性。我们得出结论,高k Al2O3的主要作用是抑制擦除过程中的栅极电子注入,而不是提高P/E速度。因此,插入缓冲氧化物只会改变EOT,而不会改变P/E机制。另一方面,缓冲氧化物可以通过Al2O3抑制泄漏,从而大大提高数据保留率。然而,由于厚底氧化物的擦除速度慢,MANOS和MAONOS擦除速度都很慢,必须使用非常高的擦除电压。此外,MANOS和MAONOS设备的耐用性在P/E≤10时也会迅速下降,这是由于电子脱陷机制造成的。此外,在多次P/E循环后,较大的擦除电压也会导致隧道氧化物的严重降解。为了兼顾速度和可靠性,有必要引入带隙工程隧道势垒(BE-MANOS)来解决带隙工程隧道势垒的基本问题。
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