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Dissertation angenommen durch: Universität Duisburg-Essen, Campus
Duisburg, Fakultät für Naturwissenschaften, Institut für Chemie,
2004-02-11
BetreuerIn: Dr. rer. nat. Alfred Golloch , Universität Duisburg-Essen, Campus Duisburg, Fakultät für Naturwissenschaften, Institut für Chemie
GutachterIn: Priv.-Doz. Dr. rer. nat. Evelin Denkhaus , Universität Duisburg-Essen, Campus Duisburg, Fakultät für Naturwissenschaften, Institut für Chemie
GutachterIn:
Priv.-Doz. Dr. Evelin Denkhaus , Universität Duisburg-Essen, Campus
Duisburg, Fakultät für Naturwissenschaften, Institut für Chemie
Schlüsselwörter in Deutsch: Gleitfunkenspektroskopie, UV/VIS Spektroskopie, Sedimentanalysen, PVC-Analysen
Schlüsselwörter in Englisch: UV/VIS spectroscopy, sedimentation analysis, PVC analysis, sliding spark spectroscopy
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Bemerkungen in Englisch
A novel direct solid-state emission spectroanalytical method based on
the pulsed sliding spark source has been developed. The technique is
characterised by a radiative transient discharge plasma propagating
along the surface of a dielectric solid matrix enforced between a pair
of electrodes in air at atmospheric pressure, where matrix excitation
is driven by plasma-particle interaction based on geometry- and source
opto-electric-modulated electron impact excitation.
This dissertation embodies the results of the systematic theoretical
and experimental study of the sliding spark which aimed at the
analytical development of the technique for trace quantitative
spectroscopy of the heavy elements embedded in the dielectric matrix
surface layers.
The optical emission spectrum, when detected and measured in the
range 212–511 nm at 0.05 nm spectral resolution using optical fibre
transmission in conjunction with a holographic blazed grating CCD
spectrometer, was found to be suitable for simultaneous multi-elemental
analysis. Investigation of the spectral characteristics of several
heavy metals embedded in a variety of dielectric matrices (a
boro-silicate simulate, borax, polyvinyl-alcohol, cellulose, teflon,
Al-Zr simulate ceramic powder, simulate and River sediment samples) has
led to the realisation of an empirical scheme for optimal
identification and selection of the optically thin lines that are
suitable for trace quantitative analysis. The utility of the lines
depends on the element and sample matrix. Use of PVC as a matrix
modifier results in increased sensitivity through formation of volatile
halides. Comprehensive characterisation of the measured spectra
provides empirical evidence to exploit the sliding spark at fast pulse
frequency also as an atom source for combined emission, fluorescence,
and absorption spectroscopy applicable to the elucidation of structural
and molecular information by temporal gating, time-resolved techniques.
Practical approaches found in the search for an appropriate calibration
strategy for quantitative analysis include the use of internal
standards based on Y and La (added) and Si and C (matrix-derived)
spectral lines, which compensate for the differing ablation yield,
signal drifts and matrix effects in and between complex matrices.
Accurate analytical models have been derived for Mn, Ti, V, Ni, Co, Cu,
Cd, Pb, Cr, Al, Fe, Zn, and Hg. A quantification methodology has been
developed based on sediment and as model matrix, which combines high
sensitivity and satisfactory reproducibility for Mn, Ti, V, Ni, Co, Cu,
Cr, Al, Fe, and Zn. Trace quantitative analysis of dielectric solid
matrices by sliding spark spectroscopy is realised in the concentration
range from several hundred ppb to thousands of ppm depending on the
analyte (and the spectral line utilized) and on the calibration
strategy adopted for the quantification. The elemental limits of
detection vary from several hundred ppb to few tens of ppm depending on
the element, analysed matrix, spectral line, and calibration method.
Qualitative speciation analysis is possible for Mn, V, Pb, Ti, Cu, and
Co. Sliding spark spectroscopy has been validated as a new, simple but
robust and versatile technique for the direct trace analysis of complex
solid dielectric and refractory matrices with a reproducibility at 12
%, a precision characterised by a confidence interval of (0.5–10) %,
and an accuracy by relative efficiency of 0–10 % by the successful
analyses of Certified Reference Materials (Stream sediments), sewage
sludge, a PVC polymer, an independent XRF laboratory analysis of River
Rhine sediment, and by the results of comparative analyses made of the
same elements using ICP and XRF (polarised radiation, 3-D Cartesian
geometry) techniques.
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