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Multi-element determinations of N,N-dimethylformamide (DMF) coal slurries using ICP-OESMujuru, M, McCrindle, RI, Botha, BM, Ndibewu, PP 01 January 2009 (has links)
a b s t r a c t
A slurry nebulisation technique was applied for elemental analysis of bituminous coals SARM 18, SARM
19 and four coals from three different seams in Witbank, South Africa, by inductively coupled plasma
optical emission spectroscopy (ICP-OES). Major elements (Al, Ca, Fe, Mg, S, Si and Ti) and trace elements
(Ba, Cr, Mn, Ni, Sr, V, Zn and Zr) in coal were determined. Various slurry preparations were evaluated
using two dispersants (glycerol and Triton X-100) and by varying the concentration of dispersants,
between 0.1% and 1.0% (v/v). The effect of initially solubilising the ground coal in N,N-dimethylformamide
(DMF) was investigated by varying the volume of DMF added. The effect of wet grinding with DMF was
investigated. Wet grinding with DMF was shown to drastically reduce particle sizes (50.0% < 0.28 lm and
90.0% < 6.17 lm) as compared to dry grinding (50.0% < 5.25 lm and 90.0% < 11.1 lm). The reduced particle
sizes and increased transport efficiency of the coal slurries led to improved analytical recoveries of
elements in the reference coal, SARM 18. The best analytical recoveries for all elements were achieved
using 0.1% Triton X-100 with 10.0% DMF. Results obtained by ICP-OES after wet grinding of the coal with
DMF, using 0.1% Triton X-100, also gave excellent recoveries (Al, 100%; Ca, 103%; Cr, 106%; Fe, 102%; Mg,
100%; Mn, 104%; Ni, 109%; Si, 102%; Ti, 95.0%; and V, 108%). The results obtained with 10.0% DMF and
0.1% Triton X-100 were in agreement with certified values for all selected elements according to paired
t-test at the 95.0% confidence level. Selected elements (Al, Ca, Fe, Mg, Mn, Si, Ti and V) were also analysed
with X-ray fluorescence for comparison with results obtained from ICP-OES. Analysis by ICP-OES of
microwave digested coal was also carried out. It is suggested that the DMF slurry technique could be used
for routine analysis of bituminous coals.
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The atomisation and determination of volatile metals in coalWilkinson, John Robert January 1981 (has links)
The analytical advantages of some novel approaches to atomisation using gaseous sample transport and slurry nebulization have been investigated and applied to the determination of trace metals in coal. A cold vapour atomic fluorescence spectroscopic method for the determination of mercury using a gas-sheathed atom cell and front surface illumination was developed. With a manual injection technique the detection limit was 0.01 ng. Replacement with a continuous flow system yielded a more rapid and precise method with a detection limit of C.045 ng.ml-1. Quantitative recoveries of mercury from a standard coal were obtained through liberation of the analyte using nonoxidative pyrolysis. Continuous hydride generation methods for the determination of arsenic and selenium using atomic absorption and atomic fluorescence spectrometry were developed.
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Solid sample introduction by Slurry Nebulization ICP-OES for determination of PGMs,gold and base metals in different matricesOchieng, Levi 02 March 2007 (has links)
Student Number : 0006342N -
PhD thesis -
School of Chemistry -
Faculty of Science / An improved slurry method for determination of PGMs, gold and base metals (Ni,
Cu, Fe and Co) using ICP-OES analytical instrument has been developed. This
method has been successfully applied to quantitate metals in mineral concentrates
and biological samples (grass, lichens, leaves and tree trunks) and validated using
analytical figure of merit that include limits of detection, limits of quantition,
accuracy and precision.
Sample grinding using Fritsch GmbH Pulverissette Planetary Mono Mill was
optimized to get > 60% and >80% of the particles to < 5.0 μm and < 10 μm
respectively. The optimum grinding conditions for a sample mass of 0.4 g was
determined as 130 rpm grinding speed and 30 minutes grinding time. An
additional 15 minutes mixing with reagent was employed to ensure better slurry
homogeneity for improved precisions.
Five slurry dispersants; tetrasodium pyrophosphate, Triton X-100, dodecylbenzene
sulfonic acid sodium salt, potassium cyanide and potassium thiocyanate, were
evaluated at varied concentrations and 0.1% v/v Triton X-100 established as the
best dispersant for slurry preparation.
The ICP-OES sample delivery system was modified by introducing an extension
elbow between the torch and the spray chamber that not only effectively reduced
the sample residence time in the plasma for efficient atomization of the particles
but also acted as a gravitational sieve eliminating larger particles and droplets.
Prepared slurries were continuously agitated using an ultrasonic bath prior to and
during aspiration into ICP-OES to prevent sedimentation and ensure constant
stability of the slurry. Optimum operating conditions for ICP-OES established as 1600 W and 1450 W plasma power for PGMs and base metals respectively, using
a nebulizer flow rate of 0.8 mL min-1, coolant gas flow rate of 13.0 mL min-1,
auxiliary gas flow rate of 1.0 L min-1 with a sample uptake rate of 0.2 mL min-1.
Limits of detection for the developed technique were determined in μg g-1 as
0.075, 0.039, 0.115, 0.071, 0.035 and 0.118 for Au, Ir, Pd, Pt, Rh and Ru
respectively and 0.15, 0.391, 0.345 and 0.217 for Ni, Cu, Fe and Co respectively.
Limits of quantitation in μg g-1 were obtained as 0.250, 0.130, 0.383, 0.237, 0.117
and 0.393 for Ir, Pd, Pt, Rh and Ru respectively and 0.5, 1.31, 1.15 and 0.723 for
Ni, Cu, Fe and Co respectively. Good accuracy was recorded for all the base
metals as well as for the platinum group metals and gold except iridium that was
susceptible to copper interference.
Two measurements of precision, reproducibility and repeatability were assessed.
Reproducibility was obtained in percentages as 12, 7.93, 5.54, 10 and 12 for Au,
Pd, Pt, Rh and Ru respectively and 9.9, 10, 9.8 and 10 for Ni, Cu, Fe and Co
respectively. Repeatability was obtained in percentages as 11, 7.03, 4.94, 8.08 and
9.85 for Au, Pd, Pt, Rh and Ru respectively and 9.4, 9.6, 9.7 and 10 for Ni, Cu, Fe
and Co respectively. Good percentage recoveries were obtained of 104.3%,
98.3%, 98%, 90.5% and 92.8% for Au, Pd, Pt, Rh and Ru respectively. Percentage
recoveries of 109%, 111%, 89.9% and 100% for Ni, Cu, Fe and Co respectively
were obtained.
The simplicity and low cost of sample preparation used in this method enables it to
be easily adopted in any ICP-OES laboratory. A single analyst may achieve more
sample through-puts than before per day (including re-grinding and analysis),
resulting in a highly economical and rapid technique for determination of metals.
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Inductively Coupled Plasma Spectrometry for Speciation Analysis : Development and ApplicationsForsgard, Niklas January 2007 (has links)
In analytical chemistry the main goal is normally to determine the identity and/or concentration of one or more species in a sample. The samples analyzed are often natural samples, containing numerous different species in a complex matrix and the choice of technique for multi-elemental detection is in general inductively coupled plasma spectrometry. The chemical forms of an element can affect many of its characteristics e.g. toxicity, which makes speciation analysis important. Therefore, determination of the identity and quantity of an element is still important, but for many applications measurements of total element concentration provides insufficient information. To be able to perform speciation analysis, separation, identification and/or characterization of the various forms of elements in the sample has to be accomplished. Speciation analysis has been employed in a wide range of disciplines, including for example environmental science, biology and clinical chemistry. This thesis describes work to improve and understand the elemental speciation analysis with liquid chromatography coupled to plasma spectrometry and also highlights the importance and potential of the synergy between atomic spectrometry and molecular mass spectrometry. The combination of the matrix tolerant, robust and very sensitive plasma spectrometry used together with molecular mass spectrometry, which provides structural information and the possibility to identify unknown species, is demonstrated to be a very powerful tool for speciation analysis. In this thesis methods are developed for on-line sample clean-up and pre-concentration coupled to liquid chromatography and plasma spectrometry, which makes handling of small sample volumes easier and also decreases the risk of contamination. The problems associated with organic modifiers in plasma spectrometry are also addressed. Applications of speciation analysis are exemplified by analysis of aluminium-chelated siderophores in field-soil solutions and organic phosphorous species in aquatic sediments. The possibility to analyze un-dissolved samples as slurries with minimal sample preparation is also discussed.
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