Hydraulic Performance of Geosynthetic Clay Liners in a Landfill Final Cover
Publication: Journal of Geotechnical and Geoenvironmental Engineering
Volume 133, Issue 7
Abstract
Percolation from a landfill final cover containing a geosynthetic clay liner (GCL) as the hydraulic barrier is described. The GCL was covered with of vegetated silty sand and underlain with two gravel-filled lysimeters to monitor percolation from the base of the cover. Higher than anticipated percolation rates were recorded in both lysimeters within after installation of the GCL. The GCL was subsequently replaced with a GCL laminated with a polyethylene geofilm on one surface (a “composite” GCL). The composite GCL was installed in two ways, with the geofilm oriented upwards or downwards. Low percolation rates have been transmitted from the composite GCL for more than regardless of the orientation of the geofilm. Samples of the conventional GCL that were exhumed from the cover ultimately had hydraulic conductivities on the order of . These high hydraulic conductivities apparently were caused by exchange of Ca and Mg for Na on the bentonite combined with dehydration. The overlying and underlying soils likely were the source of the Ca and Mg involved in the exchange. Column experiments and numerical modeling indicated that plant roots and hydraulic anomalies caused by the lysimeters were not responsible for the high hydraulic conductivity of the GCL. Despite reports by others, the findings of this study indicate that a surface layer thick is unlikely to protect conventional GCLs from damage caused by cation exchange and dehydration. Accordingly, GCLs should be used in final covers with caution unless if cation exchange and dehydration can be prevented or another barrier layer is present (geomembrane or geofilm).
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Acknowledgments
Support for the laboratory experiments and field exhumations conducted in this study was provided in part by the United States National Science Foundation (NSF) under Grant No. NSFCMS-9900336. Inc. and RMT Inc. of Madison, Wis., collected the lysimeter data. Alliant Energy permitted sampling and testing of the GCLs exhumed from the final cover and use of the lysimeter data. Assistance provided by each of these companies is gratefully acknowledged. Stephen Meer conducted some of the laboratory tests and Brian Albrecht assisted with the field work. Their assistance is greatly appreciated.
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© 2007 ASCE.
History
Received: May 3, 2006
Accepted: Nov 27, 2006
Published online: Jul 1, 2007
Published in print: Jul 2007
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