Reduction of threshold voltage fluctuation in field-effect transistors by controlling individual dopant position

Masahiro Hori; Keigo Taira; Akira Komatsubara; Kuninori Kumagai; Yukinori Ono; Takashi Tanii; Tetsuo Endoh; Takahiro Shinada

doi:10.1063/1.4733289

Reduction of threshold voltage fluctuation in field-effect transistors by controlling individual dopant position

Masahiro Hori, Keigo Taira, Akira Komatsubara, Kuninori Kumagai, Yukinori Ono, Takashi Tanii, Tetsuo Endoh, Takahiro Shinada

ENG - Electrical Engineering

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

8 Citations (Scopus)

Abstract

To investigate the impact of only the dopant position on threshold voltage (V _th) in nanoscale field-effect transistors, we fabricated transistors with ordered dopant arrays and conventional random channel doping. Electrical measurements revealed that device performance could be enhanced by controlling the dopant position alone, despite varying dopant number according to a Poisson distribution. Furthermore, device-to-device fluctuations in V _th could be suppressed by implanting a heavier ion such as arsenic owing to the reduction of the projected ion struggling. The results of our study highlight potential improvements in device performance by controlling individual dopant positions.

Original language	English
Article number	013503
Journal	Applied Physics Letters
Volume	101
Issue number	1
DOIs	https://doi.org/10.1063/1.4733289
Publication status	Published - 2012 Jul 2

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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10.1063/1.4733289

Cite this

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abstract = "To investigate the impact of only the dopant position on threshold voltage (V th) in nanoscale field-effect transistors, we fabricated transistors with ordered dopant arrays and conventional random channel doping. Electrical measurements revealed that device performance could be enhanced by controlling the dopant position alone, despite varying dopant number according to a Poisson distribution. Furthermore, device-to-device fluctuations in V th could be suppressed by implanting a heavier ion such as arsenic owing to the reduction of the projected ion struggling. The results of our study highlight potential improvements in device performance by controlling individual dopant positions.",

author = "Masahiro Hori and Keigo Taira and Akira Komatsubara and Kuninori Kumagai and Yukinori Ono and Takashi Tanii and Tetsuo Endoh and Takahiro Shinada",

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AU - Hori, Masahiro

AU - Taira, Keigo

AU - Komatsubara, Akira

AU - Kumagai, Kuninori

AU - Ono, Yukinori

AU - Tanii, Takashi

AU - Endoh, Tetsuo

AU - Shinada, Takahiro

N1 - Funding Information: This work was supported in part by the Semiconductor Research Corporation (SRC) No. 1676.001, Grants-in-Aid for Scientific Research Nos. 22681020, 23226009, and 20241036 from the Ministry of Education, Culture, Sports, Science and Technology, Japan, and Research Fellowships for Young Scientists from the Japan Society for the Promotion of Science.

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N2 - To investigate the impact of only the dopant position on threshold voltage (V th) in nanoscale field-effect transistors, we fabricated transistors with ordered dopant arrays and conventional random channel doping. Electrical measurements revealed that device performance could be enhanced by controlling the dopant position alone, despite varying dopant number according to a Poisson distribution. Furthermore, device-to-device fluctuations in V th could be suppressed by implanting a heavier ion such as arsenic owing to the reduction of the projected ion struggling. The results of our study highlight potential improvements in device performance by controlling individual dopant positions.

AB - To investigate the impact of only the dopant position on threshold voltage (V th) in nanoscale field-effect transistors, we fabricated transistors with ordered dopant arrays and conventional random channel doping. Electrical measurements revealed that device performance could be enhanced by controlling the dopant position alone, despite varying dopant number according to a Poisson distribution. Furthermore, device-to-device fluctuations in V th could be suppressed by implanting a heavier ion such as arsenic owing to the reduction of the projected ion struggling. The results of our study highlight potential improvements in device performance by controlling individual dopant positions.

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Reduction of threshold voltage fluctuation in field-effect transistors by controlling individual dopant position

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