100纳米一代CMOS多氧化物工艺中的自由基氮化

2001 Symposium on VLSI Technology. Digest of Technical Papers (IEEE Cat. No.01 CH37184) Pub Date : 2001-06-12 DOI:10.1109/VLSIT.2001.934958

Y. Yasuda, N. Kimizuka, K. Watanabe, T. Tatsumi, A. Ono, K. Fukasaku, K. Imai, N. Nakamura

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引用次数: 1

摘要

我们提出了一种新的多氧化物技术，该技术大大提高了同一芯片上高性能(HP)晶体管和低功耗(LP)晶体管的驱动电流与栅极泄漏电流的比率。关键技术是自由基氮化(Watanabe et al, apple)。理论物理。列托人。第76卷，第2940页，2000;Togo等人，超大规模集成电路技术公司。，第116页，2000)，然后是多氧化物形成。此外，与高k介电体相比，它更容易与传统的CMOS工艺集成。仅一个额外的步骤就可以将LP晶体管的等效氧化物厚度(EOT)减少0.3 nm，从而提高驱动电流(I/sub on/)。它还可以在不增加EOT的情况下将HP晶体管的栅漏电流(I/sub g/)抑制两个数量级。多氧化物的每种氧化物厚度都是可扩展的，以支持各种片上系统(SoC)应用。

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Radical nitridation in multi-oxide process for 100 nm generation CMOS technology

We propose a new multi-oxide technology, which drastically improves the ratio of the drive current to the gate leakage current for both high-performance (HP) transistors and low-power (LP) transistors on the same die. The key technology is radical nitridation (Watanabe et al, Appl. Phys. Lett. vol. 76, p. 2940, 2000; Togo et al, VLSI Tech. Symp., p. 116, 2000) followed by multi-oxide formation. In addition, it is easier to integrate with conventional CMOS processes compared with high-k dielectrics. Only one additional step reduces equivalent oxide thickness (EOT) of the LP transistor by 0.3 nm, thereby improving the drive current (I/sub on/). It also suppresses the gate leakage current (I/sub g/) for HP transistors by two orders of magnitude without an increase of EOT. Each oxide thickness of the multi-oxide is scalable to support various system-on-a-chip (SoC) applications.

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2001 Symposium on VLSI Technology. Digest of Technical Papers (IEEE Cat. No.01 CH37184)

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