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Spark Plasma Parameters for Titanium Diboride and Titanium Electrodes. Numerical Simulation and Experiment

Spark Plasma Parameters for Titanium Diboride and Titanium Electrodes. Numerical Simulation and... Numerical simulation was used to compare the effect of pure titanium and titanium diboride on the spark plasma parameters in air and the intensity of spectral lines at various erosion rates, power densities at the discharge axis, and excitation potentials of singly charged Ti II ions. The model incorporates the equation of mass transfer at the discharge axis and quasiequilibrium conditions for calculating the plasma composition on assumption of local thermodynamic equilibrium (LTE). Temperature at the discharge axis was calculated using the energy balance equation considering the energy gained by electrons in the external field and energy losses in inelastic collisions (ionization and excitation of atoms and ions, dissociation of molecules). The system of nonlinear equations was solved in the cycle to obtain self-consistent values of temperature and particle concentration. Temperature was 500–1000 K higher with TiB2 electrodes than that with Ti electrodes in all ranges of powers and erosion rates. 3D plots of temperature, electron concentration, particle densities, and line intensities were built as functions of discharge power density and erosion rates of the electrodes. The temperature, electron concentration, and intensity of spectral lines for atoms and singly and doubly charged ions of pure titanium and titanium in diboride were nonlinear functions of the discharge power and the electrode erosion rate. The nature of changes in the concentration of particles differs significantly from changes in the intensity of lines emitted by these particles. The calculated parameters agree with the experimental data within the measurement error and certain simplifications adopted in the model. The results obtained can be used both for analyzing the composition of new materials and for spectral diagnostics of electrode erosion. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Powder Metallurgy and Metal Ceramics Springer Journals

Spark Plasma Parameters for Titanium Diboride and Titanium Electrodes. Numerical Simulation and Experiment

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References (14)

Publisher
Springer Journals
Copyright
Copyright © Springer Science+Business Media, LLC, part of Springer Nature 2021
ISSN
1068-1302
eISSN
1573-9066
DOI
10.1007/s11106-021-00246-w
Publisher site
See Article on Publisher Site

Abstract

Numerical simulation was used to compare the effect of pure titanium and titanium diboride on the spark plasma parameters in air and the intensity of spectral lines at various erosion rates, power densities at the discharge axis, and excitation potentials of singly charged Ti II ions. The model incorporates the equation of mass transfer at the discharge axis and quasiequilibrium conditions for calculating the plasma composition on assumption of local thermodynamic equilibrium (LTE). Temperature at the discharge axis was calculated using the energy balance equation considering the energy gained by electrons in the external field and energy losses in inelastic collisions (ionization and excitation of atoms and ions, dissociation of molecules). The system of nonlinear equations was solved in the cycle to obtain self-consistent values of temperature and particle concentration. Temperature was 500–1000 K higher with TiB2 electrodes than that with Ti electrodes in all ranges of powers and erosion rates. 3D plots of temperature, electron concentration, particle densities, and line intensities were built as functions of discharge power density and erosion rates of the electrodes. The temperature, electron concentration, and intensity of spectral lines for atoms and singly and doubly charged ions of pure titanium and titanium in diboride were nonlinear functions of the discharge power and the electrode erosion rate. The nature of changes in the concentration of particles differs significantly from changes in the intensity of lines emitted by these particles. The calculated parameters agree with the experimental data within the measurement error and certain simplifications adopted in the model. The results obtained can be used both for analyzing the composition of new materials and for spectral diagnostics of electrode erosion.

Journal

Powder Metallurgy and Metal CeramicsSpringer Journals

Published: Sep 1, 2021

Keywords: spark plasma parameters; numerical simulation; intensity of spectral lines; titanium and titanium diboride electrodes; optical spectral analysis; spectral diagnostics of electric erosion

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