A classification study of shales in Kansas using electron-spin resonance spectroscopy

  • John M. Cubitt
  • James G. Wilkinson


Spectroscopy Shale Resonance Spectroscopy Classification Study 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.


Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.


  1. Angel, B. R., and Hall, P. H., 1972, Electron spin resonance studies of kaolins: Proc. Int. Clay Conf. (Madrid, 1972), Reprints, v. 1, p. 71–84.Google Scholar
  2. Boesman, E., and Schoemaker, D., 1961, Résonance paramagnétique de l'ion Fe3+ dans la kaolinite: Compt. Rend. Acad. Sci., v. 252, p. 1931.Google Scholar
  3. Cubitt, J. M., 1975a, A regression technique for the analysis of shales by x-ray diffractometry: Jour. Sed. Pet., v. 45, no. 2, p. 546–553.Google Scholar
  4. Cubitt, J. M., 1975b, A computer analysis of the geochemistry and mineralogy together with the petrology of the Upper Pennsylvanian and Lower Permian shales of Kansas, USA: unpubl. doctoral dissertation, Leicester Univ. (England), 366 p.Google Scholar
  5. Friedlander, H. Z., Saldick, J., and Frink, G. R., 1963, Electron spin resonance spectra in various clay minerals: Nature, v. 199, no. 4888, p. 61–62.Google Scholar
  6. Ghosh, P. K., Samaddar, M., Sinha, S. C., Tiwari, J. S., and Banerji, A. C., 1970, Geological applications of E.S.R. spectrometry: Mn2+ ions in calcium carbonate minerals: Technology, v. 7, no. 4, p. 276–280.Google Scholar
  7. Gibbs, R. J., 1967, Quantitative x-ray diffraction analysis using clay mineral standards extracted from the samples to be analysed: Clay Minerals, v. 7, p. 79–90.Google Scholar
  8. Hall, P. L., Angel, B. R., and Braven, J., 1974, Electron spin resonance and related studies of lignite and ball clay from South Devon: Chem. Geology, v. 13, no. 2, p. 97–113.Google Scholar
  9. Low, W., 1968, Electron spin resonance—a tool in mineralogy and geology: Adv. Elect. and Elect. Phys., v. 24, p. 51.Google Scholar
  10. Low, W., and Zeire, S., 1972, E.S.R. spectra of Mn2+ in heat-treated aragonite: Am. Mineral., v. 57, no. 7–8, p. 1115–1125.Google Scholar
  11. Marfunin, A. S., 1964, Radiospectroscopy of minerals: Geol. Jour., v. 4, p. 361–390.Google Scholar
  12. Morency, M., Emond, P. L., and Von Bitter, P. H., 1970, Dating conodonts using electron spin resonance: a possible technique: Kansas Geol. Survey Bull. 199, pt. 1, p. 17–19.Google Scholar
  13. Quakernaat, J., 1970, Direct diffractometric quantitative analysis of synthetic mineral mixtures with molybdenite as an orientation indicator: Jour. Sed. Pet., v. 40, no. 1, p. 506–514.Google Scholar
  14. Schindler, P., and Ghose, S., 1970, Electron paramagnetic resonance of Mn2+ in dolomite and magnesite and Mn2+ distribution in dolomites: Am. Mineral., v. 55, no. 11–12, p. 1889–1896.Google Scholar
  15. Sokal, R. R., and Sneath, P. H. A., 1963, Principles of numerical taxonomy: W. H. Freeman and Co., San Francisco, 359 p.Google Scholar
  16. Wauchope, R. D., and Haque, R., 1971, E.S.R. in clay minerals: Nature Phys. Sci., v. 233, no. 42, p. 141–142.Google Scholar
  17. Wildeman, T. R., 1969, The distribution of Mn2+ in dolomite by electron paramagnetic resonance: Am. Geophysical Union Trans., v. 50, p. 357.Google Scholar
  18. Wildeman, T. R., 1970, The distribution of Mn2+ in some carbonates by electron paramagnetic resonance: Chem. Geology, v. 5, p. 167–177.Google Scholar

Copyright information

© Plenum Publishing Corporation 1976

Authors and Affiliations

  • John M. Cubitt
    • 1
  • James G. Wilkinson
    • 2
  1. 1.Department of GeologySyracuse UniversitySyracuseUSA
  2. 2.Department of ChemistryLeicester UniversityLeicesterEngland

Personalised recommendations