Chalk fracture system characteristics: implications for flow and solute transport

doi:10.1144/GSL.QJEGH.1995.028.S1.04

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	GeoRef Citation

Quarterly Journal of Engineering Geology and Hydrogeology; 1995; v. 28; issue.Supplement_1; p. S39-S50;
DOI: 10.1144/GSL.QJEGH.1995.028.S1.04
© 1995 Geological Society of London

Article

Chalk fracture system characteristics: implications for flow and solute transport

P. L. Younger¹ & T. Elliot¹

^¹ Water Resource Systems Research Unit, Department of Civil Engineering, University of Newcastle, , Upon Tyne NE1 7RU, UK

Bulk groundwater flow and solute advection occur in the fracturesof the UK Chalk, and a knowledge of the frequency and apertureof these fractures is crucial to understanding these two keyprocesses in the Chalk. Fracture frequencies in the Chalk ofsoutheast England have been assessed regionally by means ofoutcrop scanline measurements. Measurements of radon dissolvedin Chalk groundwaters allow the estimation of fracture aperturesin the saturated zone. These data provide valuable controlson the conceptualization and estimation of hydraulic propertiesfor the Chalk aquifer. In particular, standard hydraulic modelsof fractured rock permeability applied on the basis of thesedata are shown to be insufficient to explain the higher permeabilitiesmeasured in the unconfined Chalk beneath valley axes. In thesesettings, conduit flow mechanisms must be invoked; this in turnimplies that modifications to standard matrix diffusion modelsare required to describe solute transport accurately.

Key Words: chalk • fractures • hydrogeologicalcontrols • models • radioactive tracers

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