Convergent radial tracing of viral and solute
transport in Gneiss Saprolite
Convergent radial tracing of viral and solute
transport in Gneiss Saprolite
Deeply weathered crystalline rock aquifer systems comprising unconsolidated saprolite and underlying fractured
bedrock (saprock) underlie 40% of sub-Saharan Africa. The vulnerability of this aquifer system to contamination,
particularly in rapidly urbanizing areas, remains poorly understood. In order to assess solute and viral
transport in saprolite derived from Precambrian gneiss, forced-gradient tracer experiments using chloride and Escherichia coli phage FX174 were conducted in southeastern Uganda. The bacteriophage tracer was largely unrecovered;
adsorption to the weathered crystalline rock matrix is inferred and enabled by the low pH (5.7) of site
ground water and the bacteriophage’s relatively high isoelectric point (pI ¼ 6.6). Detection of the applied FX174
phage in the pumping well discharge at early times during the experiment traces showed, however, that average
ground water flow velocities exceed that of the inert solute tracer, chloride. This latter finding is consistent with observations in other hydrogeological environments where statistically extreme sets of microscopic flow velocities are considered to transport low numbers of fecal pathogens and their proxies along a selected range of linked
ground water pathways. Application of a radial advection-dispersion model with an exponentially decaying source
term to the recovered chloride tracer estimates a dispersivity (a) of 0.8 6 0.1 m over a distance of 4.15 m. Specific yield (Sy) is estimated to be 0.02 from volume balance calculations based on tracer experiments. As singlesite observations, our estimates of saprolite Sy and a are tentative but provide a starting point for assessing the vulnerability of saprolite aquifers in sub-Saharan Africa to contamination and estimating quantitatively the impact of climate and abstraction on ground water storage.
284-294
Taylor, Richard
b6a48a6f-956a-4ba3-b3d4-529953474072
Tindimugaya, Callist
ac0a419b-0653-40fc-a5c7-e2198187e1ba
Barker, John A.
33bf9dec-cc9b-451c-8192-46099e316b6d
Macdonald, David
b80ccfca-5f50-48e0-94f2-f8b73293f40b
Kulabako, Robinah
258d9f7e-adac-4a26-81e4-23e36f281be7
2010
Taylor, Richard
b6a48a6f-956a-4ba3-b3d4-529953474072
Tindimugaya, Callist
ac0a419b-0653-40fc-a5c7-e2198187e1ba
Barker, John A.
33bf9dec-cc9b-451c-8192-46099e316b6d
Macdonald, David
b80ccfca-5f50-48e0-94f2-f8b73293f40b
Kulabako, Robinah
258d9f7e-adac-4a26-81e4-23e36f281be7
Taylor, Richard, Tindimugaya, Callist, Barker, John A., Macdonald, David and Kulabako, Robinah
(2010)
Convergent radial tracing of viral and solute
transport in Gneiss Saprolite.
Ground Water, 48 (2), .
(doi:10.1111/j.1745-6584.2008.00547.x).
Abstract
Deeply weathered crystalline rock aquifer systems comprising unconsolidated saprolite and underlying fractured
bedrock (saprock) underlie 40% of sub-Saharan Africa. The vulnerability of this aquifer system to contamination,
particularly in rapidly urbanizing areas, remains poorly understood. In order to assess solute and viral
transport in saprolite derived from Precambrian gneiss, forced-gradient tracer experiments using chloride and Escherichia coli phage FX174 were conducted in southeastern Uganda. The bacteriophage tracer was largely unrecovered;
adsorption to the weathered crystalline rock matrix is inferred and enabled by the low pH (5.7) of site
ground water and the bacteriophage’s relatively high isoelectric point (pI ¼ 6.6). Detection of the applied FX174
phage in the pumping well discharge at early times during the experiment traces showed, however, that average
ground water flow velocities exceed that of the inert solute tracer, chloride. This latter finding is consistent with observations in other hydrogeological environments where statistically extreme sets of microscopic flow velocities are considered to transport low numbers of fecal pathogens and their proxies along a selected range of linked
ground water pathways. Application of a radial advection-dispersion model with an exponentially decaying source
term to the recovered chloride tracer estimates a dispersivity (a) of 0.8 6 0.1 m over a distance of 4.15 m. Specific yield (Sy) is estimated to be 0.02 from volume balance calculations based on tracer experiments. As singlesite observations, our estimates of saprolite Sy and a are tentative but provide a starting point for assessing the vulnerability of saprolite aquifers in sub-Saharan Africa to contamination and estimating quantitatively the impact of climate and abstraction on ground water storage.
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Published date: 2010
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Local EPrints ID: 185881
URI: http://eprints.soton.ac.uk/id/eprint/185881
ISSN: 0017-467X
PURE UUID: 2392e241-94f9-4ad7-87f6-b19f84221590
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Date deposited: 11 May 2011 11:14
Last modified: 14 Mar 2024 03:16
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Author:
Richard Taylor
Author:
Callist Tindimugaya
Author:
David Macdonald
Author:
Robinah Kulabako
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