V. Hohreiter scite author profile

The interaction between laser-induced plasmas and individual particles controls the rate of particle dissociation and subsequent atomic diffusion and emission processes, with implications for single-particle spectroscopy, as well as materials synthesis and other plasma sources. It is demonstrated through quantitative plasma imaging studies that discrete particles dissociate on a time scale of tens of microseconds within plasmas formed by 300-mJ Nd:YAG laser pulses. Significant spatial nonhomogeneity, as measured by localized atomic emission from particle-derived calcium atoms, persists on a comparable time scale, providing a measure of their average atomic diffusion rate of 0.04 m(2)/s. In addition, the resulting calcium atomic emission is explored using image analysis as well as traditional spectroscopic analysis.

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Cross-correlation analysis for temperature measurement

Hohreiter

Wereley

Olsen

et al. 2002

Meas. Sci. Technol.

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The current work demonstrates an optical technique that utilizes micron-resolution particle image velocimetry (µ-PIV) for temperature measurement. The technique is based on the premise that Brownian motion will cause width-wise broadening of the cross-correlation peak. A correlation-based PIV algorithm detects the magnitude of Brownian particle motion and can be used to determine the temperature of the fluid. Results were obtained using fluorescing (rhodamine 542/612) spherical 700 nm diameter polystyrene-latex particles in water. Temperature changes up to 25 °C were determined with an experimental accuracy of ±3 °C.

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Temporal analysis of laser-induced plasma properties as related to laser-induced breakdown spectroscopy

Hohreiter

Carranza

Hahn

2004

Spectrochimica Acta Part B: Atomic Spectroscopy

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Calibration Effects for Laser-Induced Breakdown Spectroscopy of Gaseous Sample Streams: Analyte Response of Gas-Phase Species versus Solid-Phase Species

Hohreiter

Hahn

2005

Anal. Chem.

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The effects of analyte phase on the calibration response for laser-induced breakdown spectroscopy is investigated for a range of carbon species. Significant differences in the atomic emission signal from carbon were observed when comparing calibration streams of gas-phase and submicrometer-sized solid-phase carbon species. The resulting calibration curve slopes varied by a factor of 8 over a comparable range of atomic carbon concentrations for five different analyte sources, while the plasma electron density and temperature remained essentially constant. The current findings challenge a widely held assumption that complete dissociation of constituent species within a highly energetic laser-induced plasma results in independence of the analyte atomic emission signal on the analyte source. A physical model of the plasma-analyte interaction is proposed that provides a framework to account for the observed dependence on the physical state of the analyte.

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Dual-pulse laser induced breakdown spectroscopy: Time-resolved transmission and spectral measurements

Hohreiter

Hahn

2005

Spectrochimica Acta Part B: Atomic Spectroscopy

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V. Hohreiter

Plasma−Particle Interactions in a Laser-Induced Plasma: Implications for Laser-Induced Breakdown Spectroscopy

Cross-correlation analysis for temperature measurement

Temporal analysis of laser-induced plasma properties as related to laser-induced breakdown spectroscopy

Calibration Effects for Laser-Induced Breakdown Spectroscopy of Gaseous Sample Streams: Analyte Response of Gas-Phase Species versus Solid-Phase Species

Dual-pulse laser induced breakdown spectroscopy: Time-resolved transmission and spectral measurements

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