The effects of furnace N/sub 2/O annealing on MOSFETs

Liu, Ming; Krick,; Wann,; Ko,; Hu$^{, }$; Cheng, Wood-Hi

doi:10.1109/iedm.1992.307438

Cited by 8 publications

(5 citation statements)

References 5 publications

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“…It has been shown that nitridation of the gate oxide can provide a barrier to boron penetration [16], [17]. Nitrided gate oxides also have exhibited improved hot-carrier reliability, and reduced radiation degradation [16], [18]. Nitridation of the gate oxide has been shown to affect surface carrier mobility, but its effect on saturation velocity has not been studied.…”

Section: A Nitridation Of the Gate Oxidementioning

confidence: 99%

“…Namely, at low effective vertical fields a nitrided sample has electron mobility less than the "universal" value, while at high vertical fields the trend is reversed. The crossover point has been shown to be a function of N O anneal time and temperature [18]. Normally, shorter times and lower temperatures lead to crossovers at lower vertical fields.…”

Section: A Linear Mobility At Low Tangential Fieldmentioning

confidence: 99%

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High-field transport of inversion-layer electrons and holes including velocity overshoot

Assaderaghi

Sinitsky

Bokor

et al. 1997

IEEE Trans. Electron Devices

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In this paper, we experimentally address the effect of a wide range of parameters on the high-field transport of inversion-layer electrons and holes. The studied parameters include substrate doping level, surface micro-roughness, vertical field strength, nitridation of the gate oxide, and device channel length. We employ special test structures built on Silicon-On-Insulator (SOI) and bulk wafers to accurately measure the high-field drift velocity of inversion-layer carriers. Our findings point to electron velocity overshoot at room temperature, dependence of electron and hole saturation velocities on nitridation of the gate oxide, dependence of the high-field drift velocity on the effective vertical field, and relative insensitivity of electron and hole mobility and saturation velocity to moderate surface roughness.

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Section: A Nitridation Of the Gate Oxidementioning

confidence: 99%

Section: A Linear Mobility At Low Tangential Fieldmentioning

confidence: 99%

High-field transport of inversion-layer electrons and holes including velocity overshoot

Assaderaghi

Sinitsky

Bokor

et al. 1997

IEEE Trans. Electron Devices

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“…is the highest for thermal oxide and is degraded for the N Oannealed oxides. It is apparent that this reduction in is dominated by degradation of peak electron mobility in N-MOSFET's [1], [3].…”

Section: A Initial Propertiesmentioning

confidence: 96%

Reduction of RIE-damage by N/sub 2/O-anneal of thermal gate oxide

Joshi

Mann

Chung

et al. 1998

IEEE Trans. Semicond. Manufact.

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We have investigated RIE-induced damage in MOS devices with thermal oxide as well as N2O-annealed oxide as gate dielectrics. A systematic improvement in robustness against RIEinduced damage is seen when N2O flow rate and/or N2O anneal temperature are increased. We have demonstrated a N2O anneal process at 900 C, which provides a robust SiO2/Si interface against plasma damage and hot carrier stress.

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“…Okada et al showed that although the N O-nitridation significantly improved time-dependentdielectric-breakdown (TDDB) characteristics under substrateside injection, it did not improve the TDDB characteristics under gate-side injection [4]. The N O-nitrided oxides were also known to exhibit inferior MOSFET characteristics due to Si/SiO interface charges [5]- [7]. In fact, these disadvantages have hindered the popular use of N O-nitrided oxides for the commercial production.…”

Section: Introductionmentioning

confidence: 99%

Effects of nitridation pressure on the characteristics of gate dielectrics annealed in N₂O ambient

Joo

Yeo

Lee

et al. 1999

IEEE Electron Device Lett.

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Effects of N 2 O pressure during oxynitridation on the characteristics of ultrathin gate dielectrics have been investigated. Reoxidation in N 2 O ambient showed three distinguished oxidation regions as a function of tube pressure; that is, enhancement at 10-40 torr, retardation at 40-100 torr, and enhancement at 100-600 torr. The N2O-nitridation at 40 torr incorporated much less nitrogen in oxide bulk than that at near-atmospheric pressure. The 40 torr N2O-nitridation case exhibited about 70% of nitrogen incorporation at the Si/SiO2 interface compared to that of the 600 torr N2O-nitridation case. The low-pressure N2Onitridation at 40 torr results in improvement of TDDB of gate dielectrics and the transconductance of nMOSFET's compared to the nitridation at near-atmospheric pressure. These data suggest that low pressure oxynitridation should be more recommendable for device application.

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The effects of furnace N/sub 2/O annealing on MOSFETs

Cited by 8 publications

References 5 publications

High-field transport of inversion-layer electrons and holes including velocity overshoot

High-field transport of inversion-layer electrons and holes including velocity overshoot

Reduction of RIE-damage by N/sub 2/O-anneal of thermal gate oxide

Effects of nitridation pressure on the characteristics of gate dielectrics annealed in N₂O ambient

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The effects of furnace N/sub 2/O annealing on MOSFETs

Cited by 8 publications

References 5 publications

High-field transport of inversion-layer electrons and holes including velocity overshoot

High-field transport of inversion-layer electrons and holes including velocity overshoot

Reduction of RIE-damage by N/sub 2/O-anneal of thermal gate oxide

Effects of nitridation pressure on the characteristics of gate dielectrics annealed in N2O ambient

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Effects of nitridation pressure on the characteristics of gate dielectrics annealed in N₂O ambient