用于CMOS应用的先进氮化氧栅极电介质

Extended Abstracts of International Workshop on Gate Insulator (IEEE Cat. No.03EX765) Pub Date : 2003-12-19 DOI:10.1109/IWGI.2003.159201

J. Yugami, S. Tsujikawa, R. Tsuchiya, S. Saito, Y. Shimamoto, K. Torii, T. Mine, T. Onai

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引用次数: 3

摘要

在先进的CMOS中，满足ITRS路线图要求的最理想的栅极介质候选者仍然是SiON，特别是对于高性能和低功耗器件。为了提高硅栅介质的效率，关键词是富氮。高氮浓度可以降低泄漏电流，提高对杂质渗透的抗扰性。然而，在富n的硅中，由于氮原子在界面附近形成固定电荷而导致的迁移率下降和NBTI增强是一个问题。为了解决这些问题，我们开发了一种富氧界面(OI-SiN)的SiN栅极电介质。氧原子在形成SiN后结合的过程提供了增强的氮浓度和富氧界面，同时抑制固定电荷，即使在具有亚纳米EOT的电介质中也是如此。这种OI-SiN具有良好的抗杂质渗透能力，与传统的SiON相比，它提供了优越的器件性能。此外，OI-SiN作为高钾栅极堆叠的界面层，可以有效地解决高钾栅极介质中的问题。

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Advanced oxynitride gate dielectrics for CMOS applications

A most preferable candidate of gate dielectrics in advanced CMOS to satisfy the requirement of an ITRS roadmap is still SiON, especially for high-performance and low-power devices. To advance the efficiency of SiON gate dielectrics, the keyword is N-rich. A high nitrogen concentration leads to low leakage current and high immunity to impurity penetration. However, in N-rich SiON, the mobility degradation and NBTI enhancement due to fixed charges formed by incorporated nitrogen atoms near the interface are problems. To solve these problems, we developed a SiN gate dielectric with an oxygen-enriched interface (OI-SiN). A process in which oxygen atoms are incorporated after forming SiN provides enhanced nitrogen concentration and an oxygen-enriched interface while simultaneously suppressing fixed charges, even in dielectrics having sub-nm EOT. This OI-SiN has good immunity against impurity penetration and provides superior device performance compared to the conventional SiON. Furthermore, the OI-SiN was much effective as an interfacial layer of high-K gate stack to solve problems in high-K gate dielectric.

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Extended Abstracts of International Workshop on Gate Insulator (IEEE Cat. No.03EX765)

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