CAPABILITIES OF ELECTROMAGNETIC INSTALLATIONS WHEN STUDYING THE FIELDS OF INDUCED POLARIZATION

Purpose. The research is aimed at studying the behavior of space and time characteristics of the fields of induced polarization caused by electric and magnetic sources typical for geoelectric settings of the south of Siberian craton. Methods. Numerical simulation of the electromagnetic field is used to calculate the transient characteristics of a typical geoelectric model. The sensitivity of non-stationary electromagnetic sounding towards the measurement of induced polarization effects is estimated on the basis of model data analysis. To measure the depths of the polarized layers spatial inversion is applied. Results. Variations of the the polarizability coefficient and depth of the polarized layer have been analyzed for one of the 3D TEM sounding areas within the North-West part of the Nepa arch. Сonclusions. The use of the magnetic source allows to improve the reliability of the studies of conductivity and polarizability of the geological section of the south of the Siberian craton.

electrical prospecting, electric and magnetic dipoles, induced polarization, electrical resistivity, automatic inversion

1. Van`yan L.L. On the models of deep electric conductivity (review). Izvestiya Akademii nauk Soyuza Sovetskikh Sotsialisticheskikh Respublik. Fizika zemli [Izvestiya. Physics of the Solid Earth], 1981, no. 5, рр. 57–66. (In Russian).

2. Pospeev A.V., Pashevin A.M. Modeling results of the magneto-telluric field of the South of Siberian platform. Geologiya i geofizika [Russian Geology and Geophysics], 1990, no. 2, pp. 78–81. (In Russian).

3. Egorov I.V., Pospeev A.V. Comparison analysis of transient electromagnetic field sources. Geofizika [The Russian Geophysics Journal], 2015, no. 1, pp. 26–30. (In Russian).

4. Kozhevnikov N.O., Antonov E.Yu. Pulsed induction electrical survey of polarizable media. Geofizicheskii zhurnal [Geophysical Journal], 2009, no. 4, vol. 31, pp. 104–118. (In Russian).

5. Kozhevnikov N.O., Antonov E.Yu. ТЕМ data inversion considering fastdecaying induced polarization: numerical experiment based on homogeneous polarizable half-space model. Geofizika [The Russian Geophysics Journal], 2007, no. 1, pp. 42–50. (In Russian).

6. Ageenkov E.V. Ekvivalentnost` opredeleniya polyarizuemosti i vremeni relaksatsii sloya s chastotnoi dispersiei provodimosti [Determination equivalence of polarizability and time relaxation of a layer with the frequency dispersion of conductivity]. Tret`ya ural`skaya molodezhnaya nauchnaya shkola po geofizike [The Third Scientific Youth School on Geophysics]. Ekaterinburg, 2002, pp. 80–84. (In Russian).

7. Legeido P.Yu., Mandel`buam M.M., Rykhlinskii N.I. Differentialnormalized electrical measurements in direct exploration of hydrocarbon reservoirs. Geofizika [The Russian Geophysics Journal], 1995, no. 4, pp. 35–42. (In Russian).

8. Cole K.S., Cole R.H. Dispersion and absorption in dielectrics. Journal of Chemical Physics, 1941, vol. 9, no. 4, pp. 343–351.

9. Pelton W.H., Ward S.H., Hallof P.G., Sill W.R., Nelson P.H. Mineral discrimination and removal of inductive coupling with multifrequency IP. Geophysics, 1978, no. 43, pp. 588–609.

10. Pirson S.J. Significant advances in magneto-electric unconventional methods in exploration for petroleum and natural gas. Symp. II-1979. Dallas: Southern Methodist University Press, 1981, рр. 169–196.

11. Kaminskii A.E. Zondirovanie stanovleniem polya zondtem1d [Sounding by the ZondTEM1d field formation]. ZOND [ZOND]. Available at: http://zondgeo.ru/software/electromagnetic-soundings/zondtem1d (accessed 27 May 2016).

12. Mogilatov V.S. Impul`snaya elektrorazvedka [Pulsed electroprospecting]. Novosibirsk: Novosibirsk State University Publ., 2002, 208 р. (In Russian).

13. Agafonov Yu.A., Surov L.V., Sharlov M.V. Operation principle and main components of the hardware and software complex of digital telemetric electroprospecting station “Piket”. Rossiiskii geofizicheskii zhurnal [Russian Journal on Geophysics], 2006, no. 43, pp. 98–102. (In Russian).