ESPECIALLY THE MAGNETIC ORIENTATION OF PARTICLES

Authors

  • B. Urusova Karachay-Cherkess state University named after U. D. Aliyev
  • S. Тemirbolatova Kabardino-Balkarian State University named after Kh.M. Berbekova

Abstract

Experimental results are given spectral analysis of rock granite-aplite in order to reveal the chemical composition of magnetic rock ores. DF-24 was used to measure spectral analysis, and the method proposed earlier . As used to measure the natural residual magnetization. Experimental studies have shown that the magnetic phenomena in mountain granite-aplite and the conditions for the formation of natural residual magnetization in it are very specific and the following factors are observed: ferromagnetic grains are very small from 1 to 10 microns. 

The paper considers the features of magnetic orientation, in order to reveal how magnetized particles are deposited in water, how the value of the magnetic moment – µ changes in a constant magnetic field-H. Weленыfound errors of inclinati n

Author Biographies

B. Urusova , Karachay-Cherkess state University named after U. D. Aliyev

Doctor of physical and mathematical Sciences, 

Professor, head of the Department of physics

S. Тemirbolatova , Kabardino-Balkarian State University named after Kh.M. Berbekova

Art. the teacher Department of Maxillofacial Surgery and Surgical Dentistry , Institute of Dentistry and Maxillofacial Surgery Nalchik

References

Urusova B.I., Jatdoeva S.U.//Some magnetic properties of the ore mining / International scientific Research journal. Innovative science // Ufa. 2015. № 4.

Heider F., Halgedain S.L., Dunlop D. I. Temperature dependence in magnеtic crystal. / Heider F., Halgedain S.L., Dunlop D. I // Geophys. Res. Lett. – 1988. 15 - №5. – P. 199.

Markink E. M. Relaxation behaviour of spherical and cylindrical magnetic nanoparticles in liquid media // Master-Thesis, University of Twente, Netherlands (2012).

Armlio L. M., Brandt Y. L., Martthew D., Yadav S., Maestas S., Rivera A.. Iron Oxide Nanocrystals for Magnetic Hyperthermia Applications // Nanomaterials, Vol. 2, (2012), p. 134–46.

Murase K., Takata H., Takeuchi Y., Saito S.. Control of the temperature rise in magnetic hyperthermia with use of an external static magnetic field // Physica Medica, Vol. 29, (2013), p. 624-630.

Soto-Aquino D., Rinaldi C. Nonlinear energy dissipation of magnetic nanoparticles in oscillating magnetic fields // Journal of Magnetism and Magnetic Materials, Vol. 393, (2015), p. 46-55.

Pavlov P. V., Khokhlov A. F. " solid state Physics” Moscow-Higher school, 2000

Urusova B. I. Physics of magnetic phenomena of rocks./ Urusova B. I.-S.-P.: info-da, 2010. – 123p.

Rzhevsky V. V., Novik G.Ya. osnovy fiziki gornykh porod [Fundamentals of rock physics]. /Rzhevsky V. V., Novik G. Ya – - s. - P.: Lenand, 2014. - 368 p.

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Published

2020-12-11

Issue

Vol. 1 No. 43 (2020)

Section

Статьи

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