The presence of ultra-trace levels of mercury in industrial gas and condensate streams is a
cause of both environmental and production concern. The toxic nature of the element, in all
forms, together with its ability to shut-down large processing plants dictates a need for its
accurate and precise measurement.
The study which investigated the recovery of various mercury species, spiked into synthetic
and real condensate samples using conventional and new digestion and/or extraction
techniques showed recovery was dependent upon the speciation. Using the most efficient
technique, L<cysteine with persulphate, recoveries of over 90 % were obtained for diphenyl
mercury, ethyl and phenyl mercury chlorides and mercury chloride. The recovery of 15%
for the important dimethyl mercury species limits the use of this technique.
A novel technique has been developed for the determination of total mercury in complex
liquid hydrocarbons. Samples (up to 1.0 ml) were vaporised (400oC) and swept through a
gold-coated silica trap maintained at 200°C, which retained all mercury species and
discarded the matrix. The trap when heated to 900°C released the mercury for measurement
by atomic fluorescence spectrometry (AFS). The recoveries for eight mercury species
spiked (10 to 50 ng ml into toluene and condensate were generally over 90 %. The
instrumental limit of detection (LOD) was 11 pg. The total mercury content of gas
condensates, gasolines and heavy oils were determined.
Gas chromatograhy coupled, via a pyrolysis interface, with AF detection was able to
determine mercury species in gas condensate, at picogram levels (LOD: 2.5 to 7 pg) using a
direct sample injection procedure. For a given column system the positive identification and
quantification of up to eight mercury species was obtained. A maximum injector
temperature of 125oC was recommended, to avoid the conversion of species. Mass balance
calculations show a strong correlation between the total mercury content and the sum of the
lower dialkyl mercury species, for all condensate samples studied.
Three commercially available mercury removal systems, A, B and C produced a reduction in
the mercury content of hydrocarbon streams under pilot plant conditions. The two stage
system, 'A', produced a minimum of 30 % conversion from organomercury to elemental
mercury after the hydrogenation reaction in stage 1. While elemental mercury was adsorbed
by the stage 2 reactor, the organomercury species were not removed. The single stage
adsorber 'B' showed 100 % removal efficiency for three dialkyl mercury species in liquid
hydrocarbon streams. The removal efficiency for adsorber 'C was species dependent. Two
common condensate species gave values of 50 to 80 % removal efficiency while the third
species showed time-dependent bleed-off.
Date of Award | 1999 |
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Original language | English |
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Awarding Institution | |
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Mercury species in natural gas condensate
Shafawi, A. B. (Author). 1999
Student thesis: PhD