An Optima 3000 ICP-AES instrument was modified and the equipment necessary to
carry out axial excitation atomic fluorescence was designed and constructed. Using this
calibrated system, preliminary fluorescence experiments were not successful. As
fluorescence is proportional to source intensity, it was considered that the excitation
source, a hollow cathode lamp, may not have been sufficiently intense to produce
fluorescence.
A novel excitation source-driver system was designed and built in-house to operate
HCLs, BDHCLs and LEDs with variable modulation frequencies and duty cycle
capabilities. Studies investigating lamp response to changes in modulation frequency
and duty cycle indicated that a lamp operated with a lower modulation frequency range
(167 - 542 Hz) and higher duty cycles (30 - 50 %) should provide the preferred intense
excitation conditions for the production of fluorescence in the ICP, When a Thermo
Elemental PQ2 instrument was used, fluorescence was obtained immediately.
Um'variate searches were used to optimise several plasma parameters, i.e. forward
power; viewing height ALC; plasma, nebuliser and auxiliary gas flow rates. Once the
optimum conditions had been determined, calibration curves were plotted for each of
the elements studied (Ba, Li, Mg and Na). The calibration showed excellent linearity
over five orders of magnitude (R? values ranged from 0.99995 to 1.0000) and the
precision on each data point was better than 5 % RSD. Limits of detection were
determined to be 27.6, 0.51, 0.43 and 0.20 ug 1* for Ba, L i , Mg and Na, respectively,
which approached those reported in the literature for a commercial system.
Vertical profiles of the plasma, using radial excitation, were obtained for Ba, Li , Mg and
Na. Using the optimum conditions for Li and Na, vertical profiles of the plasma, using
axial excitation with the more intense LEDs, were obtained. Both profiles showed that
there was a relatively sharp optimum, with respect to fluorescence signal, as a function
of viewing height ALC. The optimum viewing heights ALC obtained, for both radial
and axial excitation fluorescence, were identical, suggesting that, irrespective of the
excitation arrangement employed, only particular conditions produced in the plasma
give the optimum conditions for fluorescence and that these are spatially dependent.
Plasma diagnostics were performed in an attempt to explain why fluorescence was
observed using the plasma produced by the Thermo Elemental but not by the Optima
3000 generator. At a viewing height of 50 mm ALC, Texc and Trot were 3080 and 2500
K for plasmas produced using the Thermo Elemental generator and 3600 and 2830 K
for the Optima 3000 generator, respectively. Temperatures were calculated using the
mean emission intensity at particular wavelengths. The intensities of the emitting
species from the Thermo Elemental ICP were lower than those obtained from the
Optima 3000 ICP for supposedly 'identical' conditions. If the number of excited species
gives rise to lower emission intensities, then there must be more atoms in the
lower/ground state from the plasma produced using the Thermo Elemental generator.
This is of vital importance because for fluorescence to occur the fluorescence emission
intensity will be dependent on the number available in the ground state for excitation
{i.e. a relatively 'cool' plasma is required for fluorescence to occur). As very similar
plasma operating conditions and the same concentration solutions were used in the
fluorescence experiments performed using both the Optima 3000 and the Thermo
Elemental ICPs, the differences observed in plasma performance may be attributed to
efficiency of coupling of the generators used.
Date of Award | 2002 |
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Original language | English |
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Awarding Institution | |
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FLUORESCENCE STUDIES IN THE INDUCTIVELY COUPLED PLASMA
Young, A. (Author). 2002
Student thesis: PhD