具有最佳高k厚度的势垒工程Al2O3和HfO2高k电荷捕获器件(BE-MAONOS和BE-MHONOS)的研究

2010 IEEE International Memory Workshop Pub Date : 2010-05-16 DOI:10.1109/IMW.2010.5488382

S. Lai, Chih-Ping Chen, P. Du, H. Lue, D. Heh, Chih-Yen Shen, F. Hsueh, H. Wu, J. Liao, J. Hsieh, M.T. Wu, F. Hsu, S. Hong, C. Yeh, Yung-tai Hung, K. Hsieh, Chih-Yuan Lu

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引用次数: 3

摘要

结合Al2O3和HfO2高k层的势垒工程电荷捕获装置的行为已被严格检查。我们建议在BE-MAONOS和BE-MHONOS上使用较厚的缓冲氧化物(6纳米)和较薄的(5纳米)高k顶部盖层，以提高可靠性。更薄的高k封盖层减少了高温烘烤下快速的初始电荷损失。此外，它还减少了不希望的瞬态读电流松弛。这些影响是由于高k材料在编程/擦除过程中大量捕获电荷造成的。通过减少高k厚度，这些可靠性问题可以最小化。我们还发现HfO2比Al2O3具有更好的厚度缩放能力。最后，展示了一种高性能BE-SHONOS(具有n+-poly栅极和HfO2顶部封盖层)晶体管。

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A study of barrier engineered Al2O3 and HfO2 high-K charge trapping devices (BE-MAONOS and BE-MHONOS) with optimal high-K thickness

The behavior of barrier engineered charge trapping devices incorporating Al2O3 and HfO2 high-K layers has been critically examined. We propose to use a thicker buffer oxide (≫ 6 nm) and thin (≪5nm) high-K top capping layer for BE-MAONOS and BE-MHONOS in order to improve the reliability. Thinner high-K top capping layer reduces the fast initial charge loss under high-temperature baking. Moreover, it also reduces the undesired transient read current relaxation. These effects are due to the bulk trapped charge in high-K material during programming/erasing. By reducing the high-K thickness these reliability issues can be minimized. We also found that HfO2 has a better thickness scaling capability than Al2O3. Finally, a high-performance BE-SHONOS (with n⁺-poly gate and HfO2 top capping layer) transistor is demonstrated in this work.

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2010 IEEE International Memory Workshop

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