Hostname: page-component-76fb5796d-9pm4c Total loading time: 0 Render date: 2024-04-26T03:32:46.723Z Has data issue: false hasContentIssue false
  • English
  • Français

Measurement of Moisture Content and Density of Soil Masses Using Radioactivity Methods

Published online by Cambridge University Press:  01 January 2024

Irving Goldberg ,
L. J. Trescony ,
J. S. Campbell Jr.  and
G. J. Whyte
Irving Goldberg
Affiliation:
University of California, USA
L. J. Trescony
Affiliation:
University of California, USA
J. S. Campbell Jr.
Affiliation:
University of California, USA
G. J. Whyte
Affiliation:
University of California, USA
Get access Rights & Permissions [Opens in a new window]

Abstract

This paper deals with the application of methods involving the scattering of neutrons and gamma rays to the measurement of moisture content and density of granular materials. The measurement of moisture content is based on the principle that when fast neutrons emitted from a radioactive source collide with hydrogen atoms they are slowed down to a much greater extent than by collisions with other atoms. The number of slow neutrons thus produced is a measure of the number of hydrogen atoms present in the vicinity of the source. Water is the principal contributor of hydrogen atoms in a soil medium. A probe, containing a source of fast neutrons and a slow neutron detector, is inserted into the soil. The probe is connected by a cable to a suitably calibrated scaling instrument, and the moisture content determined from the count rate.

The density of a soil is measured with a probe that is similar but provided with a source and a detector of gamma radiation. The gamma rays emitted from this source are scattered by collisions with electrons of atoms in their path. The higher the density of the surrounding medium, the greater the scattering. In the range of densities normally occurring in soils, greater scattering results in fewer gamma rays returning to the detector. Thus, the density of the medium can also be related to the count rate obtained with the scaling instrument.

The advantages of the radioactivity methods are that continuous or repeated measurements of moisture content and density at any desired depth can be made, and that measurements are integrated over a large volume of soil, so that representative values are obtained. In addition, water may be detected in the solid or vapor states as well as in the liquid state. The soil undergoes a minimum of disturbance because the probe is lowered into an access tube slightly greater than 1 inch in diameter. Measurements can be made in a short time; once the access tube has been placed, it takes an average of about six minutes to determine both moisture content and density at a given depth. The instruments are not influenced by ordinary temperature changes. The method appears to be relatively independent of soil type, so that a single calibration curve for moisture content, and one for density, may be applicable to a wide range of materials.

A description of the theory of scattering of neutrons and gamma rays is included in this report as well as a discussion of the various types of sources and detectors which can be employed in the procedure. Field and laboratory tests utilizing these instruments are described, and the accuracy of test results discussed.

It is concluded that application of this method will provide a rapid, simple and accurate means for measuring moisture content and density of soils or similar granular materials. On this basis, recommendations for future research and more extensive applications of the method are reviewed.

Type
Article
Information
Clays and Clay Minerals (National Conference on Clays and Clay Minerals) , Volume 3 , February 1954 , pp. 516 - 548
Copyright
Copyright © The Clay Minerals Society 1954

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Belcher, D. J., Cuykendall, T. R., and Sack, H. S. (1950) The measurement of soil moisture and density by neutron and gamma-ray scattering: Technical Development Report No. 127, U.S. Civil Aeronautics Administration, Technical Development and Evaluation Center, Indianapolis, Indiana, 20 pp.Google Scholar
Belcher, D. J., Cuykendall, T. R., and Sack, H. S. (1952) Nuclear meters for measuring soil moisture in thin surface layers: Technical Development Report No. 161, U.S. Civil Aeronautics Administration, Technical Development and Evaluation Center, Indianapolis, Indiana, 8 pp.Google Scholar
Belcher, D. J., Herner, R. C., Cuykendall, T. R., and Sack, H. S. (1952) Use of radioactive material to measure soil moisture and density: Symposium on the Use of Radioisotopes in Soil Mechanics, Special Technical Publication No. 134, American Society for Testing Materials, Philadelphia, Pa., pp. 1022.Google Scholar
Carlton, P. F., Belcher, D. J., Cuykendall, T. R., and Sack, H. S. (1953) Modifications and tests of radioactive probes for measuring soil moisture and density: Technical Development Report No. 194, U.S. Civil Aeronautics Administration, Technical Development and Evaluation Center, Indianapolis, Indiana, 13 pp.Google Scholar
DeJuren, J. A., and Rosenwasser, H. (1953) Diffusion length of thermal neutrons in water: Journal of Research of the National Bureau of Standards, vol. 51, No. 4, pp. 203207.CrossRefGoogle Scholar
Gardner, W., and Kirkham, D. (1952) Determination of soil moisture by neutron scattering: Soil Science, vol. 73, pp. 391401.CrossRefGoogle Scholar
Horonjeff, R., and Goldberg, I. (1953) Field measurements of soil moisture and density with radioactive materials: Proceedings, Highway Research Board, National Research Council, vol. 32, pp. 500507.Google Scholar
Horonjeff, R., Goldberg, I., and Trescony, L. J. (1954) Proceedings, Sixth Annual Street and Highway Conference, University of California, Los Angeles, pp. 136147.Google Scholar
Hosticka, H. E. (1952) Radioisotopes and nuclear reactions applied to soil mechanics problems: Symposium on the Use of Radioisotopes in Soil Mechanics, Special Technical Publication No. 134, American Society for Testing Materials, Philadelphia, Pa., pp. 39.Google Scholar
Hughes, D. J. (1953) Pile neutron research: Addison-Wesley, Cambridge, Mass., 386 pp.Google Scholar
Javete, D. F. (1954) A study of the effect of placement of access tubes upon the results of determining moisture and density of soils using radioactive materials: Institute of Transportation and Traffic Engineering Student Report No. 14, University of California, Berkeley, 16 pp.Google Scholar
Kerr, P. F., et al. (1951) Analytical data on reference clay minerals: Preliminary Report No. 7 in Reference Clay Minerals, Research Project No. 49, American Petroleum Institute, New York, N.Y., pp. 3858.Google Scholar
Kreuger, P. G. (1950) Soil density by gamma ray scattering: Thesis, Cornell University, Ithaca, N.Y., 59 pp.Google Scholar
Lane, D. A., Torchinsky, B. B., and Spinks, J. W. T. (1952) Determining soil moisture and density by nuclear radiation: Symposium on the Use of Radioisotopes in Soil Mechanics, Special Technical Publication No. 134, American Society for Testing Materials, Philadelphia, Pa., pp. 2334.Google Scholar
Pieper, G. F. Jr. (1949) The measurement of moisture content of soil by the slowing of neutrons: Thesis, Cornell University, Ithaca, N.Y., 55 pp.Google Scholar
Underwood, N., van Bavel, C. H. M., and Swanson, R. W. (1954) A portable slow neutron flux meter for measuring soil moisture: Soil Science, vol. 77, pp. 339340.Google Scholar
Vomocil, J. A. (1954) In situ measurement of bulk density of soil moisture by gamma ray absorption technique: Soil Science, vol. 77, pp. 341342.Google Scholar
Whyte, G. J. (1954) Moisture and density measurements in granular materials by radioactivity methods: Thesis, University of California, Berkeley, Calif.Google Scholar
Yates, E. P. (1950) Soil moisture determination by neutron scattering: Thesis, Cornell University, Ithaca, N.Y., 45 pp.Google Scholar