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Fabric of Consolidated Kaolinite

Published online by Cambridge University Press:  01 July 2024

R. Torrence Martin  and
Charles C. Ladd
R. Torrence Martin
Affiliation:
Geotechnical Division, Department of Civil Engineering. M.I.T., Cambridge, Massachusetts 02139, USA
Charles C. Ladd
Affiliation:
Geotechnical Division, Department of Civil Engineering. M.I.T., Cambridge, Massachusetts 02139, USA
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Abstract

Fabric refers to the spacial arrangement of clay particles in a sample relative to a reference plane. X-ray diffraction data yield an ‘amount of orientation’ (AO) that varies from zero for ideal random to 100 for ideally oriented fabric. The AO has been related to the average angle of inclination of clay particles to the reference plane.

Fabric data from 50 samples involving 2000 determinations are presented on the effects of: the method of sample preparation prior to one-dimensional consolidation; the magnitude of consolidation stress from 0·1 to over 1000 kg/cm2; changes in direction of consolidation stress; isotropic consolidation; and disturbance during removal of samples from oedometer cells. The single most important variable was the method of sample preparation, as illustrated by the following data on samples consolidated one-dimensionally to 1·5 kg/cm2:clay initially moist, AO = 27 per cent; air-dry clay, AO = 44 per cent; clay slurries, AO = 76–95 per cent. The change in fabric with increasing consolidation stress was most pronounced with samples at very low stresses, the changes in fabric were small for consolidation stress increments usually encountered in engineering practice.

Fabric data provide a very sensitive measure of sample disturbance. Extrusion causes significant disturbance at the center of a 24cm dia, sample cylinder.

Type
Research Article
Information
Clays and Clay Minerals , Volume 23 , Issue 1 , February 1975 , pp. 17 - 25
Copyright
Copyright © 1975, The Clay Minerals Society

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References

Brooker, E. W. and Ireland, H. O., (1965) Earth Pressure at Rest Related to Stress History Can. Geotech. J. 2 115.CrossRefGoogle Scholar
Engelhardt, W. and Gaida, K. H., (1963) Concentration Changes of Pore Solutions During Compaction of Clay Sediments J. sedim. Petrol. 33 919930.CrossRefGoogle Scholar
Kenney, T. C., (1967) Measurements of In Situ Stresses in Quick Clays Proc. Geotech. Conf. Oslo. 1 4956.Google Scholar
Lambe, T. W., (1960) Compacted Clay Trans. Am. Soc. Civ. Engrs. 125 682756.CrossRefGoogle Scholar
Martin, R. T., (1962) Research on the Physical Properties of Marine Soils: M.I.T. Department of Civil Engineering Soils Division Publication Number 127.Google Scholar
Martin, R. T., (1966) Quantitative Fabric of Wet Kaolinite Clays and Clay Minerals. 14 271287.10.1346/CCMN.1966.0140124CrossRefGoogle Scholar
Meade, R. H., (1966) Factors Influencing the Early Stages of the Compaction of Clays and Sands—Review J. sedim. Ferrol. 36 10851101.Google Scholar
Mitchell, J. K., (1964) Shearing Resistance of Soils as a Rate Process J. Soil Mech. Fdns., Am. Soc. civ. Engrs. 90 2961.Google Scholar
Morgenstern, N. R. and Tchalenko, J. S., (1967) The Optical Determination of Preferred Orientation in Clays and its Application to the Study of Microstructure in Consolidated Kaolin Proc. R. Soc. 300 218250.Google Scholar
O’Brien, N. R., (1964) Origin of Pennsylvanian Underlays in the Illinois Basin Bull. Geolog. Soc. Am. 75 823832.CrossRefGoogle Scholar
Olsen, H. W., (1960) Hydraulic Flow Through Saturated Gays Proc. 9th Conf., Clays and Clay Minerals. 9 131160.Google Scholar
Olsen, R. E. and Mesri, G., (1970) Mechanisms Controlling Compressibility of Clays J. Soil Mech. Fans. Div. Am. Soc. civ. Engrs. 96 18631878.Google Scholar
Quigley, R. M., (1962) The Engineering Properties of Illite Related to Fabric and Pore Water Composition 16th Can. Soil Mech. Conf. .Google Scholar
Quigley, R. M. and Orunbadejo, T. A., (1972) Clay Layer Fabric and Oedometer Consolidation of Soft Clay Can. Geotech. J. 9 165175.10.1139/t72-017CrossRefGoogle Scholar
Quigley, R. M. and Thompson, C. D., (1966) The Fabric of Anisotropically Consolidated Sensitive Marine Clay Can. Geotech. J. 3 6173.10.1139/t66-008CrossRefGoogle Scholar
Seed, H. B. and Chan, C. K., (1961) Structure and Strength Characteristics of Compacted Clay Trans. Am. Soc. civ. Engrs. 126 13441385.10.1061/TACEAT.0008131CrossRefGoogle Scholar
Thiem, H. K., (1967) Quantitative Textaranalyze Durch Rontgenintensitatsmessungen und ihre Anwerdung auf experimentell verdichtete kaolinit-und montomorillonit-Tone Doktors Dissertation Eberhard-Karls-Universitat za Tubingen .Google Scholar
Van Olphen, H., (1951) Rheological Phenomena of Clay Soils in Connection with the Charge Distribution on the Micelles Discussion Faraday Soc. 11 8284.10.1039/df9511100082CrossRefGoogle Scholar