Molecular Characteristics of Phosphoric Acid Treated Soils
The expansive nature of soils containing high
amounts of clay minerals can be altered through chemical
stabilization, resulting in a material suitable for construction
purposes. The primary objective of this investigation was to
study the changes induced in the molecular structure of
phosphoric acid stabilized bentonite and lateritic soil using
Nuclear Magnetic Resonance (NMR) and Fourier Transform
Infrared (FTIR) spectroscopy. Based on the obtained data, it
was found that a surface alteration mechanism was the main
reason responsible for the improvement of treated soils.
Furthermore, the results indicated that the Al present in the
octahedral layer of clay minerals were more amenable to
chemical attacks and also partly responsible for the formation
of new products.
[1] O. G. Ingles and J. B. Metcalf, Soil stabilization - principles and
practice, Melbourne: Butterworth, 1972.
[2] J. W. Lyons and G. J. McEwan, "Phosphoric acid in soil stabilization,
part I. Effect on engineering properties of soils," Highway Research
Board Bulletin 318, Washington, D.C., 1962, pp. 4-14.
[3] J. Sutton and E. McAlexander, "Soil improvement committee -
Admixture report," Geotechnical Special Publication No. 12, New York:
ASCE, 1987, pp. 123-124.
[4] J. Medina and H. N. Guida, "Stabilization of Lateritic soils with
phosphoric acid," Journal of Geotechnical and Geological Engineering,
vol. 13, 1995, pp. 199-216.
[5] H. F. Winterkorn, "Introductory remarks," Highway Research Board
Bulletin 318, Washington, D.C., 1962, pp. 1-3.
[6] M. L. McKelvy, T. R. Britt, B. L. Davis, J. K. Gillie, L. A. Lentz, A.
Leugers, R. A. Nyquist, and C. L. Putzig, "Infrared Spectroscopy,"
Analytical Chemistry, vol. 68, 1996, pp. 93-160.
[7] B. Stuart, Modern Infrared Spectroscopy, New York and UK: John
Wiley & Sons, 1996.
[8] V. C. Farmer, The Infrared Spectra of Minerals, London: Mineralogical
Society, 1974.
[9] R. A. Kinsey, R. J. Kirkpatrick, J. Hower, K. A. Smith, and E. Oldfield,
"High resolution aluminum-27 and silicon-29 nuclear magnetic
resonance spectroscopic study of layer silicates, including clay
minerals," American Mineralogist, vol. 70, 1985, pp. 537-548.
[10] G. Engelhardt and D. Michel, High resolution solid state NMR of
silicates and zeolites, UK: John Wiley & Sons, 1987.
[11] P. F. Barron, P. Slade, and R. L. Frost, "Solid-state silicon-29 spinlattice
relaxation in several 2:1 phyllosilicate minerals," Journal of
Physical Chemistry, vol. 89, 1985, pp. 3305-3310.
[12] C. P. Herrero, J. Sanz, and J. M. Serratosa, "Tetrahedral cation ordering
in layer silicates by 29Si NMR spectroscopy," Solid State
Communications, vol. 53, 1985, pp. 151-154.
[13] C. A. J. Weiss, S. P. Altaner, and R. J. Kirkpatrick, "High-resolution 29Si
NMR spectroscopy of 2:1 layer silicates: Correlations among chemical
shift, structural distortions, and chemical variations," American
Mineralogist, vol. 72, 1987, pp. 935-942.
[14] BSI, "British Standard methods of test for soils for civil engineering
purposes: Part 4, Compaction-related tests," BS1377. London: British
Standards Institution, 1990.
[15] BSI, "Stabilized materials for civil engineering purposes: Part 2,
Methods of test for cement-stabilized and lime-stabilized materials,"
BS1924. London: British Standards Institution, 1990.
[16] J. Madejova and P. Komadel, "Baseline studies of the clay minerals
society source clays: Infrared methods," Clays and Clay Minerals, vol.
49, no. 5, 2001, pp. 410-432.
[17] H. W. V. D. Marel and H. Beutelspacher, Atlas of infrared spectroscopy
of clay minerals and their admixtures, Amsterdam: Elsevier Scientific
Publishing Company, 1976.
[18] K. Nacamoto, Infrared spectra of inorganic and coordinated
compounds, New York: John Wiley & Sons, 1970.
[1] O. G. Ingles and J. B. Metcalf, Soil stabilization - principles and
practice, Melbourne: Butterworth, 1972.
[2] J. W. Lyons and G. J. McEwan, "Phosphoric acid in soil stabilization,
part I. Effect on engineering properties of soils," Highway Research
Board Bulletin 318, Washington, D.C., 1962, pp. 4-14.
[3] J. Sutton and E. McAlexander, "Soil improvement committee -
Admixture report," Geotechnical Special Publication No. 12, New York:
ASCE, 1987, pp. 123-124.
[4] J. Medina and H. N. Guida, "Stabilization of Lateritic soils with
phosphoric acid," Journal of Geotechnical and Geological Engineering,
vol. 13, 1995, pp. 199-216.
[5] H. F. Winterkorn, "Introductory remarks," Highway Research Board
Bulletin 318, Washington, D.C., 1962, pp. 1-3.
[6] M. L. McKelvy, T. R. Britt, B. L. Davis, J. K. Gillie, L. A. Lentz, A.
Leugers, R. A. Nyquist, and C. L. Putzig, "Infrared Spectroscopy,"
Analytical Chemistry, vol. 68, 1996, pp. 93-160.
[7] B. Stuart, Modern Infrared Spectroscopy, New York and UK: John
Wiley & Sons, 1996.
[8] V. C. Farmer, The Infrared Spectra of Minerals, London: Mineralogical
Society, 1974.
[9] R. A. Kinsey, R. J. Kirkpatrick, J. Hower, K. A. Smith, and E. Oldfield,
"High resolution aluminum-27 and silicon-29 nuclear magnetic
resonance spectroscopic study of layer silicates, including clay
minerals," American Mineralogist, vol. 70, 1985, pp. 537-548.
[10] G. Engelhardt and D. Michel, High resolution solid state NMR of
silicates and zeolites, UK: John Wiley & Sons, 1987.
[11] P. F. Barron, P. Slade, and R. L. Frost, "Solid-state silicon-29 spinlattice
relaxation in several 2:1 phyllosilicate minerals," Journal of
Physical Chemistry, vol. 89, 1985, pp. 3305-3310.
[12] C. P. Herrero, J. Sanz, and J. M. Serratosa, "Tetrahedral cation ordering
in layer silicates by 29Si NMR spectroscopy," Solid State
Communications, vol. 53, 1985, pp. 151-154.
[13] C. A. J. Weiss, S. P. Altaner, and R. J. Kirkpatrick, "High-resolution 29Si
NMR spectroscopy of 2:1 layer silicates: Correlations among chemical
shift, structural distortions, and chemical variations," American
Mineralogist, vol. 72, 1987, pp. 935-942.
[14] BSI, "British Standard methods of test for soils for civil engineering
purposes: Part 4, Compaction-related tests," BS1377. London: British
Standards Institution, 1990.
[15] BSI, "Stabilized materials for civil engineering purposes: Part 2,
Methods of test for cement-stabilized and lime-stabilized materials,"
BS1924. London: British Standards Institution, 1990.
[16] J. Madejova and P. Komadel, "Baseline studies of the clay minerals
society source clays: Infrared methods," Clays and Clay Minerals, vol.
49, no. 5, 2001, pp. 410-432.
[17] H. W. V. D. Marel and H. Beutelspacher, Atlas of infrared spectroscopy
of clay minerals and their admixtures, Amsterdam: Elsevier Scientific
Publishing Company, 1976.
[18] K. Nacamoto, Infrared spectra of inorganic and coordinated
compounds, New York: John Wiley & Sons, 1970.
@article{"International Journal of Architectural, Civil and Construction Sciences:49412", author = "Amin Eisazadeh and Khairul Anuar Kassim and Hadi Nur", title = "Molecular Characteristics of Phosphoric Acid Treated Soils", abstract = "The expansive nature of soils containing high
amounts of clay minerals can be altered through chemical
stabilization, resulting in a material suitable for construction
purposes. The primary objective of this investigation was to
study the changes induced in the molecular structure of
phosphoric acid stabilized bentonite and lateritic soil using
Nuclear Magnetic Resonance (NMR) and Fourier Transform
Infrared (FTIR) spectroscopy. Based on the obtained data, it
was found that a surface alteration mechanism was the main
reason responsible for the improvement of treated soils.
Furthermore, the results indicated that the Al present in the
octahedral layer of clay minerals were more amenable to
chemical attacks and also partly responsible for the formation
of new products.", keywords = "Bentonite, Laterite clay, Molecularcharacterization, Phosphoric acid, Stabilization", volume = "4", number = "3", pages = "56-3", }
