Thermally-enhanced remote plasma nitrided ultrathin (1.65 nm) gate oxide with excellent performances in reduction of leakage current and boron diffusion

C. H. Chen; Y. K. Fang; C. W. Yang; S. F. Ting; Y. S. Tsair; M. C. Yu; Tuo-Hung Hou; M. F. Wang; S. C. Chen; C. H. Yu; M. S. Liang

doi:10.1109/55.936349

Thermally-enhanced remote plasma nitrided ultrathin (1.65 nm) gate oxide with excellent performances in reduction of leakage current and boron diffusion

C. H. Chen^*, Y. K. Fang, C. W. Yang, S. F. Ting, Y. S. Tsair, M. C. Yu, Tuo-Hung Hou, M. F. Wang, S. C. Chen, C. H. Yu, M. S. Liang

^*Corresponding author for this work

Institute of Electronics

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

Ultrathin thermally enhanced remote plasma nitrided oxides (TE-RPNO) with equivalent oxide thickness down to 1.65 nm are fabricated to investigate their leakage current reduction and boron diffusion barrier performances. PMOSFET with TE-RPNO, compared to its conventional oxide counter-part, yields almost one order magnitude lower gate leakage current, less flatband voltage changes in high boron implantation dose or activation temperature, and shows broader process windows in the tradeoff between boron penetration and dopant activation.

Original language	English
Pages (from-to)	378-380
Number of pages	3
Journal	IEEE Electron Device Letters
Volume	22
Issue number	8
DOIs	https://doi.org/10.1109/55.936349
State	Published - 1 Aug 2001

Keywords

Boron penetration
Remote plasma nitridation
RPN
Ultrathin

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Chen, C. H., Fang, Y. K., Yang, C. W., Ting, S. F., Tsair, Y. S., Yu, M. C., Hou, T.-H., Wang, M. F., Chen, S. C., Yu, C. H., & Liang, M. S. (2001). Thermally-enhanced remote plasma nitrided ultrathin (1.65 nm) gate oxide with excellent performances in reduction of leakage current and boron diffusion. IEEE Electron Device Letters, 22(8), 378-380. https://doi.org/10.1109/55.936349

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abstract = "Ultrathin thermally enhanced remote plasma nitrided oxides (TE-RPNO) with equivalent oxide thickness down to 1.65 nm are fabricated to investigate their leakage current reduction and boron diffusion barrier performances. PMOSFET with TE-RPNO, compared to its conventional oxide counter-part, yields almost one order magnitude lower gate leakage current, less flatband voltage changes in high boron implantation dose or activation temperature, and shows broader process windows in the tradeoff between boron penetration and dopant activation.",

keywords = "Boron penetration, Remote plasma nitridation, RPN, Ultrathin",

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AU - Chen, C. H.

AU - Fang, Y. K.

AU - Yang, C. W.

AU - Ting, S. F.

AU - Tsair, Y. S.

AU - Yu, M. C.

AU - Hou, Tuo-Hung

AU - Wang, M. F.

AU - Chen, S. C.

AU - Yu, C. H.

AU - Liang, M. S.

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N2 - Ultrathin thermally enhanced remote plasma nitrided oxides (TE-RPNO) with equivalent oxide thickness down to 1.65 nm are fabricated to investigate their leakage current reduction and boron diffusion barrier performances. PMOSFET with TE-RPNO, compared to its conventional oxide counter-part, yields almost one order magnitude lower gate leakage current, less flatband voltage changes in high boron implantation dose or activation temperature, and shows broader process windows in the tradeoff between boron penetration and dopant activation.

AB - Ultrathin thermally enhanced remote plasma nitrided oxides (TE-RPNO) with equivalent oxide thickness down to 1.65 nm are fabricated to investigate their leakage current reduction and boron diffusion barrier performances. PMOSFET with TE-RPNO, compared to its conventional oxide counter-part, yields almost one order magnitude lower gate leakage current, less flatband voltage changes in high boron implantation dose or activation temperature, and shows broader process windows in the tradeoff between boron penetration and dopant activation.

KW - Boron penetration

KW - Remote plasma nitridation

KW - RPN

KW - Ultrathin

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Thermally-enhanced remote plasma nitrided ultrathin (1.65 nm) gate oxide with excellent performances in reduction of leakage current and boron diffusion

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Keywords

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