PDF
Abstract
Soil-bentonite (SB) vertical slurry cutoff wall is a useful treatment for urban industrial contaminated sites. Due to the clay-heavy metal interaction, significant changes would occur in the engineering behavior of SB cutoff walls. However, previous study is limited to kaolinitic soils or montmorillonitic soils along using solidum chloride and/or calcium chloride as target contaminant. In this work, a series of oedometer tests were conducted to investigate the effects of lead (Pb) on the compressibility and the permeability of kaolin-bentonite (KB) mixtures, a simplified model of in-situ SB cutoff wall backfills. In addition, sedimentation tests were conducted to interpret the mechanism controlling the change of compressibility and permeability from the perspective of soil fabric. The Pb-contaminated KB mixtures for oedometer tests and sedimentation tests were prepared with bentonite contents of 0, 5%, 10%, and 15% by dry mass, and they were mixed with pre-determined volume of lead nitrate solution based on designed Pb concentration and solid-to-solution ratio. The Pb concentration was controlled as 0, 0.1, 0.5, 1.0, 5.0, 10, and 50 mg/g with a solid-to-solution ratio of approximate 0.5. The prepared KB mixtures with bentonite contents of 0, 5%, and 10% were chosen for the sedimentation tests. They were freeze-dried and mixed with DDI with a solid-to-solution ratio of 10 g/100 mL. The results indicate that pH, compressibility, and permeability of KB mixture changed considerably with respect to Pb concentration. It is concluded that the fabric of KB mixture, depending on the particle-particle interaction subjected to different ranges of pH and Pb concentration, governs the sedimentation behavior and permeability. The results of liquid limit (wL) cannot be explained in terms of the sedimentation behavior since it is only ionic-dependent.
Keywords
slurry cutoff wall
/
kaolin
/
bentonite
/
compressibility
/
sedimentation behavior
Cite this article
Download citation ▾
Ri-dong Fan, Yan-jun Du, Song-yu Liu, Zuo-bo Chen.
Engineering behavior and sedimentation behavior of lead contaminated soil-bentonite vertical cutoff wall backfills.
Journal of Central South University, 2013, 20(8): 2255-2262 DOI:10.1007/s11771-013-1732-3
| [1] |
UNITED STATES ENVIRONMENTAL PROTECTION AGENCY US EPA.Evaluation of subsurface engineered barriers at waste sites [ER/OL], 1998
|
| [2] |
YeoS S, ShackelfordC D, EvansJ C. Consolidation and hydraulic conductivity of nine model soil-bentonite backfills [J]. Journal of Geotechnical and Geoenvironmental Engineering©ASCE, 2005, 131(10): 1189-1198
|
| [3] |
MalusisM A, BarbenE J, EvansJ C. Hydraulic conductivity and compressibility of soil-bentonite backfill amended with activated carbon [J]. Journal of Geotechnical and Geoenvironmental Engineering©ASCE, 2009, 135(5): 664-672
|
| [4] |
HongC S, ShackelfordC D, MalusisM A. Consolidation and hydraulic conductivity of zeolite amended soil-bentonite backfills [J]. Journal of Geotechnical and Geoenvironmental Engineering©ASCE, 2011, 138(1): 15-25
|
| [5] |
DuY-j, FanR-dong. Compressibility and permeability behavior of two types of amended soil-bentonite vertical cutoff wall backfills. [J]_Rock and Soil Mechanics, 2011, 32(Supp.1): 49-54
|
| [6] |
MishraA K, OhtsuboM, LiL, HigashiT. Controlling factors of the swelling of various bentonites and their correlations with the hydraulic conductivity of soil-bentonite mixtures[J]. Applied Clay Science, 2011, 52(1/2): 78-84
|
| [7] |
MitchellJ K, SogaKFundamentals of soil behavior [M], 2005Hoboken, New JerseyJohn Wiley & Sons, Inc.143-169
|
| [8] |
MarcialD, DelageP, CuiY J. Effect of exchangeable cations on the compressibility of bentonite clays [C]. Proceedings of the Workshop on Chemo-Mechanical Coupling in Clays; From Nano-scale to Engineering Applications. Maratea, Italy, 2001177-187
|
| [9] |
WangY H, SiuW K. Structure characteristics and mechanical properties of kaolinite soils: II. Effects of structure on mechanical properties [J]. Canadian Geotechnical Journal, 2006, 43(6): 601-617
|
| [10] |
PalominoA M, SantamarinaJ C. Fabric map for kaolinite: Effects of pH and ionic concentration on behavior [J]. Clays and Clay Minerals, 2005, 53(3): 209-222
|
| [11] |
SantamarinaJ C, KleinK A, PalominoA, GuimaraesM S. Micro-scale aspects of chemical-mechanical coupling: Interparticle forces and fabric [C]. Proceedings of the Workshop on Chemo-Mechanical Coupling in Clays; From Nano-scale to Engineering Applications. Maratea, Italy, 200147-64
|
| [12] |
ShawS A, Jim HendryM. Geochemical and mineralogical impacts of H2SO4 on clays between pH 5.0 and -3.0 [J]. Applied Geochemistry, 2009, 24(2): 333-345
|
| [13] |
WangY H, SiuW K. Structure characteristics and mechanical properties of kaolinite soils: I. Surface charges and structural characterizations [J]. Canadian Geotechnical Journal, 2006, 43(6): 587-600
|
| [14] |
EvansJ C, CostaM J, CooleyB. The state-of-stress in soil-bentonite slurry trench cutoff walls [C]. Geoenvironment 2000: Characterization, Containment, Remediation, and Performance in Environmental Geotechnics. New Orleans, Louisiana, 19951173-1191
|
| [15] |
ImaiG. Settling behavior of clay suspension [J]. Soils and Foundations, 1980, 20(2): 61-77
|
| [16] |
MaK, PierreA C. Sedimentation behavior of a fine kaolinite in the presence of fresh Fe electrolyte [J]. Clays and Clay Minerals, 1992, 40(5): 586-592
|
| [17] |
SridharanA, PrakashK. Settling behaviour and clay mineralogy [J]. Soils and Foundations, 2001, 41(2): 105-109
|
| [18] |
KayaA, OrenA H, YukselenY. Settling behavior and zeta potential of kaolinite in aqueous media [C]. Proceedings of the 13th International Offshore and Polar Engineers Conference. Honolulu, Hawaii, USA, 2003407-412
|
| [19] |
NasserM S, JamesA E. Settling and sediment bed behaviour of kaolinite in aqueous media [J]. Separation and Purification Technology, 2006, 51(1): 10-17
|
| [20] |
van OlphenHAn introduction to clay colloid chemistry: For clay technologists, geologists, and soil scientists [M], 19772nd edNew YorkWiley88-105
|
| [21] |
KashirM, YanfulE K. Compatibility of slurry wall backfill soils with acid mine drainage [J]. Advances in Environmental Research, 2000, 4(3): 251-268
|
| [22] |
KashirM, YanfulE. Hydraulic conductivity of bentonite permeated with acid mine drainage [J]. Canadian Geotechnical Journal, 2001, 38(5): 1034-1048
|
| [23] |
SridharanA, RaoS M, MurthyN S. Compressibility behaviour of homoionized bentonites [J]. Géotechnique, 1986, 36(4): 551-564
|
| [24] |
di MaioC. Exposure of bentonite to salt solution: Osmotic and mechanical effects [J]. Géotechnique, 1996, 46(4): 695-707
|
| [25] |
SridharanA, PrakashK. Influence of clay mineralogy and pore-medium chemistry on clay sediment formation [J]. Canadian Geotechnical Journal, 1999, 36(5): 961-966
|
| [26] |
MontoroM A, FranciscaF M. Soil Permeability controlled by particle-fluid interaction [J]. Geotechnical and Geological Engineering, 2010, 28(6): 851-864
|
| [27] |
ZimmieT F, AlmalehL J. Shrinkage of soil specimens during preparation for porosimetry tests [R]. Montreal, Canada: Soil Specimen Preparation for Laboratory Testing, Special Technical Publication (STP) 599, American Society for Testing and Materials, 1976
|
| [28] |
WilliamsD, WilliamsK. Electrophoresis and zeta potential of kaolinite [J]. Journal of Colloid and Interface Science, 1978, 65(1): 79-87
|
| [29] |
HuY, LiuX. Chemical composition and surface property of kaolins [J]. Minerals Engineering, 2003, 16(11): 1279-1284
|
| [30] |
HuY, LiuX. Chemical composition and surface property of kaolins [J]. Minerals Engineering, 2003, 16(11): 1279-1284
|
| [31] |
Dohnalová, SvobodaL, ŠulcováP. Characterization of kaolin dispersion using acoustic and electroacoustic spectroscopy [J]. Journal of Mining and Metallurgy B: Metallurgy, 2008, 44(1): 63-72
|
| [32] |
GuptaV, HamptonM A, StokesJ R, NguyenA V, MillerJ D. Particle interactions in kaolinite suspensions and corresponding aggregate structures [J]. Journal of Colloid and Interface Science, 2011, 359(1): 95-103
|
| [33] |
YongR N, OuhadiV R, GoodarziA R. Effect of Cu2+ ions and buffering capacity on smectite microstructure and performance [J]. Journal of Geotechnical and Geoenvironmental Engineering©ASCE, 2009, 135(12): 1981-1985
|
| [34] |
YangN, BarbourS L. The impact of soil structure and confining stress on the hydraulic conductivity of clays in brine environments [J]. Canadian Geotechnical Journal, 1992, 29(5): 730-739
|
