The National Grid Transco Company sponsored this project in order to promote the understanding of
NAPL migration through b-horizon soils and retarding effects upon non aqueous species migration.
Soil structure and texture was also studied using conservative (Bromide) and non-conservative
(Phosphate) tracers. Experimental data was produced using a laboratory ½ metre scale
automated lysimeter designed and constn1cted at Plymouth.
The tracers were compared before oil injection, to calibrate differences in soil texture, and after oil
injection to detect any changes in the flow patterns caused by the oil injection. It was found that the
Crediton, Sollom and Conway soils respectively offered least resistance to the tracers with the non-conservative
tracer behaving much more unpredictably than the conservative tracer. After oil injection
it could be seen that the oil had heavily retarded the ability of the tracers to migrate from the injection
site. This retardation was identified as analogous to perturbations of the soil structure. Statistical
analysis of the data showed that the experiments were all internally self consistent and visible patterns
could be seen in the corrected data caused by inclusion of oil in the injection site. Methods of dispersal
for the oil and tracer are suggested in the concluding chapter with references to the work of previous
authors.
Development of a hazard assessment framework was facilitated by the simulation of soil structures using
a pedo transfer function developed at the National Soils Resource Institute. To allow the modelling of
soils the Pore-Cor software had an annealed simplex algorithm integrated into the data inversion engine
to allow the simulation of 3-D soil structures using 2-D data from pedo transfer functions or
experimentally derived water retention curves. An extensive sensitivity analysis upon the model
highlighted limitations, due to the data set the current pedo transfer function is based upon. It was
suggested that inclusion of choices of different pedo transfer functions could be used to overcome this
problem. A suitable framework was derived for the identification of priority soils using a validated
computer model.
Experimental data was compared to the simulated data in order to try and develop an understanding of
practical upscaling of the data. The use of the "Scaleway" method is discussed in the concluding
Chapter.
Date of Award | 2004 |
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Original language | English |
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Awarding Institution | |
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Aqueous & Non-Aqueous Phase Tracer Migration Through Differing Soil Textures
Johnson, A. (Author). 2004
Student thesis: PhD