Naoshi Itabashi scite author profile

Infrared diode laser absorption spectroscopy (IRLAS) was applied to the measurement of SiH3 in a RF silane P-CVD chamber with parallel plate electrodes. The spatial distribution of SiH3 radicals between the electrodes was measured to obtain the incident flux density of SiH3 to the electrode surface. The growth rate of a-Si:H was also measured in the same plasma. These data were used to estimate the contribution of SiH3 to a-Si:H thin-film growth.

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Detection of the silylene ν2 band by infrared diode laser kinetic spectroscopy

Yamada

Kanamori

Hirota

et al. 1989

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The ν2 band of the silylene SiH2 molecule in X̃ 1 A1 was observed for the first time in the gas phase by using infrared diode laser kinetic spectroscopy. Silylene molecules were generated by the photolysis of phenylsilane at 193 nm. The observed spectrum was analyzed to determine the rotational and centrifugal distortion constants in the ground and v2 =1 states and the band origin ν0 =998.6241(3) cm−1 with one standard deviation in parentheses. The significance of the derived parameters is discussed in detail.

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Mechanism of Radical Control in Capacitive RF Plasma for ULSI Processing

Tatsumi

Hayashi

Morishita

et al. 1998

Jpn. J. Appl. Phys.

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The radicals of capacitive plasmas actually used in mass production were analyzed using various measurement systems. The composition of radicals in bulk plasma depends on the gas chemistry, the dissociation process, and interaction with the wall. It is revealed that parent gas (C4F8) is dissociated by multiple collision with electrons according to τ·n e<σv>, where τ is the residence time, n e is the electron density, σ is the dissociation collision cross section and v is the electron velocity. A high-performance etching process, which can realize 0.09 µmφ contact holes with aspect ratio of 11, was achieved using a short residence time to suppress the excess dissociation and the control of deposition species through the addition of O2 to C4F8/Ar plasma as well as the reduction of the density of F radicals through the reaction with the Si wall.

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A Model Analysis of Feature Profile Evolution and Microscopic Uniformity during Polysilicon Gate Etching in Cl₂/O₂ Plasmas

Osano

Mori

Itabashi

et al. 2006

Jpn. J. Appl. Phys.

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A phenomenological model has been developed to simulate the feature profile evolution of polycrystalline silicon (poly-Si) gate etching in Cl 2 /O 2 plasmas. The model takes into account the deposition of etch products, surface oxidation, and the forward reflection of energetic ions on feature sidewalls. To describe the formation of multilayer SiCl x or SiCl x O y on feature surfaces during etching, the substrates consist of a number of small cells or lattices of atomic size in the computational domain; this model provides a nanometer-scale representation of the feature geometry and the chemical constituents therein. The inelastic or nonspecular reflection of incoming ions from feature surfaces and the penetration of ions into substrates are incorporated into the model by calculating the trajectory of ions through successive binary collisions with substrate atoms. Etching experiments were performed to evaluate and improve the accuracy of the model. To analyze the effects of the control variables of a plasma reactor on profile evolution, the simulated profiles for different gas flow ratios and incident ion energies were compared with the etched profiles obtained in the experiments. The numerical results reproduced the behaviors of profile anomalies such as sidewall tapering and microtrenches at the corner of the feature bottom, upon varying the incident fluxes of O neutrals and etch by-products, and the incident energy of ions. Moreover, the simulated profiles exhibited passivation layers deposited on feature sidewalls, which is a similar geometry to those obtained in the experiments.

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Diffusion Coefficient and Reaction Rate Constant of the SiH₃ Radical in Silane Plasma

Itabashi

Kato

Nishiwaki

et al. 1989

Jpn. J. Appl. Phys.

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We study the dynamics of a three-dimensional laser bullet propagating inside a nonlinear saturable medium. We show that an increase of the pump parameter destabilizes the bullet and leads to its destruction through oscillations with increasing amplitude. We propose an inhomogeneous and anisotropic external excitation mechanism leading to a stable oscillating bullet. By varying the frequency of the external excitation, a stable quasi-in-phase or quasi-antiphase internal state can be reached.

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Naoshi Itabashi

Spatial Distribution of SiH₃ Radicals in RF Silane Plasma

Detection of the silylene ν2 band by infrared diode laser kinetic spectroscopy

Mechanism of Radical Control in Capacitive RF Plasma for ULSI Processing

A Model Analysis of Feature Profile Evolution and Microscopic Uniformity during Polysilicon Gate Etching in Cl₂/O₂ Plasmas

Diffusion Coefficient and Reaction Rate Constant of the SiH₃ Radical in Silane Plasma

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Naoshi Itabashi

Spatial Distribution of SiH3 Radicals in RF Silane Plasma

Detection of the silylene ν2 band by infrared diode laser kinetic spectroscopy

Mechanism of Radical Control in Capacitive RF Plasma for ULSI Processing

A Model Analysis of Feature Profile Evolution and Microscopic Uniformity during Polysilicon Gate Etching in Cl2/O2 Plasmas

Diffusion Coefficient and Reaction Rate Constant of the SiH3 Radical in Silane Plasma

Contact Info

Product

Resources

About

Spatial Distribution of SiH₃ Radicals in RF Silane Plasma

A Model Analysis of Feature Profile Evolution and Microscopic Uniformity during Polysilicon Gate Etching in Cl₂/O₂ Plasmas

Diffusion Coefficient and Reaction Rate Constant of the SiH₃ Radical in Silane Plasma