Marincan Pardede scite author profile

It is found in this work that variation of laser power density in low-pressure plasma spectrochemical analysis of hydrogen affects sensitively the hydrogen emission intensity from the unwanted and yet ubiquitous presence of ambient water. A special experimental setup has been devised to allow the simple condition of focusing/defocusing the laser beam on the sample surface. When applied to zircaloy-4 samples prepared with various hydrogen impurity concentrations using low-pressure helium surrounding gas, good-quality hydrogen emission lines of very high signal to background ratios were obtained with high reproducibility under weakly focused or largely defocused laser irradiation. These measurements resulted in a linear calibration line with nonzero intercept representing the residual contribution from the recalcitrant water molecules. It was further shown that this can be evaluated and taken into account by means of the measured intensity ratio between the oxygen and zirconium emission lines. We have demonstrated the applicability of this experimental approach for quantitative determination of hydrogen impurity concentrations in the samples considered.

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Direct Observation of Developed Plastic Deformation and Its Application to Nondestructive Testing

Yoshida

RiniWidiastuti

Pardede

et al. 1996

Jpn. J. Appl. Phys.

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An atom or molecule illuminated by a laser has its states modified by the laser. We define a set of laser-distorted states and obtain the equation for the amplitude of the wavefunction for change of population of these states. The state equation is solved approximately in a novel gauge in the limit where the laser frequency is high, and the utility of this gauge is discussed. The equation is also investigated in the limit of intense fields where it is shown that the effect of the laser is to make the internal interactions of the atom non-local. The effect of this non-locality is investigated at large distances.AMP(B) 9 / 1 5 -~

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Observation of plastic deformation wave in a tensile-loaded aluminum-alloy

Yoshida¹,

Siahaan²,

Pardede³

et al. 1999

Physics Letters A

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Characteristics of Hydrogen Emission in Laser Plasma Induced by Focusing Fundamental Q-sw YAG Laser on Solid Samples

Idris¹,

Kurniawan²,

Lie³

et al. 2004

Jpn. J. Appl. Phys.

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Hydrogen emission has been studied in laser plasma by focusing a Nd-YAG laser (1,064 nm, 50 mJ, 8 ns) on various types of samples, such as copper plate, zinc plate and glass plate. Several parameters influencing the emission were varied, such as the type of gas (air, nitrogen and helium), gas pressures (ranging from 2 up to 760 Torr) and laser power density. It was found that H emission with a narrow spectral width occurs with high efficiency when the laser plasma is produced in the low-pressure region. It was also confirmed that the conventional well-known laser-induced breakdown spectroscopy (LIBS), which usually carried out at atmospheric air pressure, cannot be applied for the analysis of hydrogen as impurity. This specific characteristic of the pressure dependence of hydrogen is interpreted based on our shock wave model, taking account of the fact that the hydrogen mass is extremely light compared to that of the host elements.

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Some notes on the role of meta-stable excited state of helium atom in laser-induced helium gas breakdown spectroscopy

et al. 2007

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