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RESEARCH PRODUCT
Tomographic diagnostics of high-frequency electrodeless lamps in argon–mercury mixtures
Natalia DenisovaG. RevaldeAtis SkudraEgils Boganssubject
Tomographic reconstructionGas-discharge lampArgonAcoustics and UltrasonicsAnalytical chemistrychemistry.chemical_elementCondensed Matter PhysicsSurfaces Coatings and FilmsElectronic Optical and Magnetic Materialslaw.inventionMercury (element)chemistrylawExcited stateAtomPlasma diagnosticsTomographyAtomic physicsdescription
Tomographic reconstruction of spatial profiles of the mercury atom density in the excited state 7 3S1 in high-frequency electrodeless lamps (HFELs) has been performed. The measurements of the Hg 546.1 nm line emission intensity have been made for the HFELs in argon–mercury mixture depending on the operation regime with different cold spot temperatures in the range 31–98 °C. The maximum entropy-based algorithm was applied for the reconstruction of local emission coefficients from the integrated intensities. The emission coefficients are directly related to the local values of the mercury atom density in the excited state 7 3S1, the upper state of the 546.1 nm transition. Such an investigation has been performed first for the HFEL. We have found that the emitting mercury atoms in the state 7 3S1 are concentrated in a thin layer located close to the lamp wall. The radial profiles have demonstrated a strong depletion of the population density in the state 7 3S1 from the lamp centre at high generator currents and low mercury vapour density. The obtained results are analysed theoretically in the context of the radial cataphoresis phenomenon. We found a qualitative agreement between the reconstructed density profiles and theoretical model predictions.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2006-03-03 | Journal of Physics D: Applied Physics |