Title page for ETD etd-08132001-175622

Type of Document Dissertation
Author Britton, Jeremy Paul
URN etd-08132001-175622
Title Soil-Bentonite Cutoff Walls: Hydraulic Conductivity and Contaminant Transport
Degree PhD
Department Civil Engineering
Advisory Committee
Advisor Name Title
Filz, George M. Committee Co-Chair
Little, John C. Committee Co-Chair
Mitchell, James K. Committee Member
Westman, Erik Christian Committee Member
Widdowson, Mark A. Committee Member
  • hydraulic conductivity
  • contaminant transport
  • soil-bentonite cutoff walls
  • Subsurface Barrier Test Facility
Date of Defense 2001-08-08
Availability unrestricted

Soil-bentonite cutoff walls are commonly used to contain contaminants in the subsurface. A key property in determining the effectiveness of a cutoff wall is its hydraulic conductivity. There are important difficulties and uncertainties regarding the accuracy of commonly used methods of measuring the hydraulic conductivity of cutoff walls.

When predicting contaminant transport through cutoff walls, common practice is to use the average hydraulic conductivity of the wall. There are some cases, however, such as circumferential cutoff walls with inward hydraulic gradients, where it is also important to consider the variability in hydraulic conductivity from point to point in the wall in contaminant transport studies.

A pilot-scale facility was envisioned where subsurface barrier issues such as those mentioned above could be studied. In 1998, the Subsurface Barrier Test Facility (SBTF) was constructed. In this facility, pilot-scale subsurface barriers can be installed using real construction equipment and tested in a controlled environment.

The effectiveness of various methods of measuring the hydraulic conductivity of cutoff walls was studied by building and testing three pilot-scale soil-bentonite cutoff walls at the SBTF. The following currently used test methods were evaluated: API tests on grab samples, lab tests on undisturbed samples, piezometer tests (slug tests), and piezocone soundings. The use of slug tests in cutoff walls was improved in this research in the areas of avoiding hydraulic fracture and accounting for the close proximity of the trench walls. The SBTF allows for measurement of the global, average hydraulic conductivity of an installed pilot-scale cutoff wall, which is a useful value to compare to the results of the above-mentioned tests. The two main factors differentiating the results of the different test methods used for the pilot-scale walls were remolding and sample size. Remolding of the API samples significantly reduced the hydraulic conductivity of these samples compared to the hydraulic conductivity measured in lab tests on undisturbed samples, which were of similar size. For the other tests, the degree and extent of remolding were less significant compared to in the API tests. For these tests, the scale of the measurement is believed to be the main factor differentiating the results. Hydraulic conductivity was found to increase as the sample volume increased, with the global measurement of the average hydraulic conductivity producing the highest value.

The influence of variability in hydraulic conductivity on contaminant transport through cutoff walls was studied from a theoretical standpoint using the one-dimensional advection-diffusion equation. Charts were developed that can be used to estimate the flux through a cutoff wall based on knowledge of the average hydraulic conductivity of the wall and an estimate of the variability in hydraulic conductivity. Data sets of hydraulic conductivity from lab tests on soil-bentonite samples from four cutoff wall case histories were used to estimate typical values of variability. The contaminant transport analyses showed that the effect of variability may be significant when the hydraulic gradient opposes the concentration gradient, which is the case for a circumferential cutoff wall with an inward hydraulic gradient. The goal of a circumferential cutoff wall with an inward hydraulic gradient is to reduce the outward diffusive flux of contaminant by inducing an inward advective flux. The effect of variability in hydraulic conductivity is to reduce the effectiveness of this scheme.

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  01_Title_page.pdf 58.02 Kb 00:00:16 00:00:08 00:00:07 00:00:03 < 00:00:01
  02_Abstract.pdf 59.21 Kb 00:00:16 00:00:08 00:00:07 00:00:03 < 00:00:01
  03_Acknowledgements.pdf 56.54 Kb 00:00:15 00:00:08 00:00:07 00:00:03 < 00:00:01
  04_Table_of_Contents.pdf 114.72 Kb 00:00:31 00:00:16 00:00:14 00:00:07 < 00:00:01
  05_List_of_Figures.pdf 129.25 Kb 00:00:35 00:00:18 00:00:16 00:00:08 < 00:00:01
  06_List_of_Tables.pdf 65.08 Kb 00:00:18 00:00:09 00:00:08 00:00:04 < 00:00:01
  07_Chapter_1.pdf 92.21 Kb 00:00:25 00:00:13 00:00:11 00:00:05 < 00:00:01
  08_Chapter_2.pdf 2.51 Mb 00:11:36 00:05:58 00:05:13 00:02:36 00:00:13
  09_Chapter_3.pdf 1.18 Mb 00:05:28 00:02:48 00:02:27 00:01:13 00:00:06
  10_Chapter_4.pdf 1.68 Mb 00:07:46 00:03:59 00:03:29 00:01:44 00:00:08
  11_Chapter_5.pdf 4.90 Mb 00:22:41 00:11:39 00:10:12 00:05:06 00:00:26
  12_Chapter_6.pdf 2.55 Mb 00:11:49 00:06:04 00:05:19 00:02:39 00:00:13
  13_Chapter_7.pdf 1.14 Mb 00:05:15 00:02:42 00:02:22 00:01:11 00:00:06
  14_Chapter_8.pdf 170.14 Kb 00:00:47 00:00:24 00:00:21 00:00:10 < 00:00:01
  15_Bibliography.pdf 165.47 Kb 00:00:45 00:00:23 00:00:20 00:00:10 < 00:00:01
  16_Appendix_A.pdf 229.69 Kb 00:01:03 00:00:32 00:00:28 00:00:14 00:00:01
  17_Appendix_B.pdf 147.21 Kb 00:00:40 00:00:21 00:00:18 00:00:09 < 00:00:01
  18_Appendix_C.pdf 99.92 Kb 00:00:27 00:00:14 00:00:12 00:00:06 < 00:00:01
  19_Appendix_D.pdf 89.32 Kb 00:00:24 00:00:12 00:00:11 00:00:05 < 00:00:01
  20_Appendix_E.pdf 144.65 Kb 00:00:40 00:00:20 00:00:18 00:00:09 < 00:00:01
  21_Vita.pdf 49.06 Kb 00:00:13 00:00:07 00:00:06 00:00:03 < 00:00:01

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