A Comparative Study of High-Field Endurance for NH3-Nitrided and N2O-Oxynitrided Ultrathin SiO2 Films

Hisashi FUKUDA

A Comparative Study of High-Field Endurance for NH₃-Nitrided and N₂O-Oxynitrided Ultrathin SiO₂ Films

Hisashi FUKUDA

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Two kinds of nitrided ultrathin (510 nm) SiO₂ films were formed on the silicon (100) face using rapid thermal NH₃-nitridation (RTN) and rapid thermal N₂O-oxynitridation (RTON) technologies. The MOS capacitors with RTN SiO₂ film showed that by Fowler-Nordheim (F-N) electron injection, both electron trap density and low-field leakage increase by the NH₃-nitridation. In addition, the charge-to-breakdown (Q_BD) value decreases owing to NH₃-nitridation. By contrast, RTON SiO₂ films exhibited extremely low electron trap density, almost no increase of the leakage current, and large Q_BD value above 200C/cm². The oxide film composition was evaluated by secondary ion mass spectroscopy (SIMS). The chemical bonding states were also examined by Fourier transform-infrared reflection attenuated total reflectance (FT-IR ATR) and X-ray photoelectron spectroscopy (XPS) measurements. These results indicate that although a large number of nitrogen (N) atoms are incorporated by the RTN and RTON, only the RTN process generates the hydrogen-related species such as NH and SiH bounds in the film, whereas the RTON film indicates only SiN bonds in bulk SiO₂. From the dielectric and physical properties of the oxide films, it is considered that the oxide wearout by high-field stress is the result of the electron trapping process, in which anomalous leakage due to trap-assisted tunneling near the injected interface rapidly increases, leading to irreversible oxide failure.

Publication: IEICE TRANSACTIONS on Electronics Vol.E76-C No.4 pp.511-518

Publication Date: 1993/04/25

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Type of Manuscript: Special Section PAPER (Special Issue on Sub-Half Micron Si Device and Process Technologies)

Category: Device Technology

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Hisashi FUKUDA, "A Comparative Study of High-Field Endurance for NH3-Nitrided and N2O-Oxynitrided Ultrathin SiO2 Films" in IEICE TRANSACTIONS on Electronics, vol. E76-C, no. 4, pp. 511-518, April 1993, doi: .
Abstract: Two kinds of nitrided ultrathin (510 nm) SiO₂ films were formed on the silicon (100) face using rapid thermal NH₃-nitridation (RTN) and rapid thermal N₂O-oxynitridation (RTON) technologies. The MOS capacitors with RTN SiO₂ film showed that by Fowler-Nordheim (F-N) electron injection, both electron trap density and low-field leakage increase by the NH₃-nitridation. In addition, the charge-to-breakdown (Q_BD) value decreases owing to NH₃-nitridation. By contrast, RTON SiO₂ films exhibited extremely low electron trap density, almost no increase of the leakage current, and large Q_BD value above 200C/cm². The oxide film composition was evaluated by secondary ion mass spectroscopy (SIMS). The chemical bonding states were also examined by Fourier transform-infrared reflection attenuated total reflectance (FT-IR ATR) and X-ray photoelectron spectroscopy (XPS) measurements. These results indicate that although a large number of nitrogen (N) atoms are incorporated by the RTN and RTON, only the RTN process generates the hydrogen-related species such as NH and SiH bounds in the film, whereas the RTON film indicates only SiN bonds in bulk SiO₂. From the dielectric and physical properties of the oxide films, it is considered that the oxide wearout by high-field stress is the result of the electron trapping process, in which anomalous leakage due to trap-assisted tunneling near the injected interface rapidly increases, leading to irreversible oxide failure.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/e76-c_4_511/_p

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@ARTICLE{e76-c_4_511,
author={Hisashi FUKUDA, },
journal={IEICE TRANSACTIONS on Electronics},
title={A Comparative Study of High-Field Endurance for NH3-Nitrided and N2O-Oxynitrided Ultrathin SiO2 Films},
year={1993},
volume={E76-C},
number={4},
pages={511-518},
abstract={Two kinds of nitrided ultrathin (510 nm) SiO₂ films were formed on the silicon (100) face using rapid thermal NH₃-nitridation (RTN) and rapid thermal N₂O-oxynitridation (RTON) technologies. The MOS capacitors with RTN SiO₂ film showed that by Fowler-Nordheim (F-N) electron injection, both electron trap density and low-field leakage increase by the NH₃-nitridation. In addition, the charge-to-breakdown (Q_BD) value decreases owing to NH₃-nitridation. By contrast, RTON SiO₂ films exhibited extremely low electron trap density, almost no increase of the leakage current, and large Q_BD value above 200C/cm². The oxide film composition was evaluated by secondary ion mass spectroscopy (SIMS). The chemical bonding states were also examined by Fourier transform-infrared reflection attenuated total reflectance (FT-IR ATR) and X-ray photoelectron spectroscopy (XPS) measurements. These results indicate that although a large number of nitrogen (N) atoms are incorporated by the RTN and RTON, only the RTN process generates the hydrogen-related species such as NH and SiH bounds in the film, whereas the RTON film indicates only SiN bonds in bulk SiO₂. From the dielectric and physical properties of the oxide films, it is considered that the oxide wearout by high-field stress is the result of the electron trapping process, in which anomalous leakage due to trap-assisted tunneling near the injected interface rapidly increases, leading to irreversible oxide failure.},
keywords={},
doi={},
ISSN={},
month={April},}

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TY - JOUR
TI - A Comparative Study of High-Field Endurance for NH3-Nitrided and N2O-Oxynitrided Ultrathin SiO2 Films
T2 - IEICE TRANSACTIONS on Electronics
SP - 511
EP - 518
AU - Hisashi FUKUDA
PY - 1993
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E76-C
IS - 4
JA - IEICE TRANSACTIONS on Electronics
Y1 - April 1993
AB - Two kinds of nitrided ultrathin (510 nm) SiO₂ films were formed on the silicon (100) face using rapid thermal NH₃-nitridation (RTN) and rapid thermal N₂O-oxynitridation (RTON) technologies. The MOS capacitors with RTN SiO₂ film showed that by Fowler-Nordheim (F-N) electron injection, both electron trap density and low-field leakage increase by the NH₃-nitridation. In addition, the charge-to-breakdown (Q_BD) value decreases owing to NH₃-nitridation. By contrast, RTON SiO₂ films exhibited extremely low electron trap density, almost no increase of the leakage current, and large Q_BD value above 200C/cm². The oxide film composition was evaluated by secondary ion mass spectroscopy (SIMS). The chemical bonding states were also examined by Fourier transform-infrared reflection attenuated total reflectance (FT-IR ATR) and X-ray photoelectron spectroscopy (XPS) measurements. These results indicate that although a large number of nitrogen (N) atoms are incorporated by the RTN and RTON, only the RTN process generates the hydrogen-related species such as NH and SiH bounds in the film, whereas the RTON film indicates only SiN bonds in bulk SiO₂. From the dielectric and physical properties of the oxide films, it is considered that the oxide wearout by high-field stress is the result of the electron trapping process, in which anomalous leakage due to trap-assisted tunneling near the injected interface rapidly increases, leading to irreversible oxide failure.
ER -

A Comparative Study of High-Field Endurance for NH₃-Nitrided and N₂O-Oxynitrided Ultrathin SiO₂ Films

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