RADIO PHYSICS AND RADIO ASTRONOMY

Subject and Purpose. The existing interest in nanosized magnetic materials requires equipment for express post-synthesis measurements of magnetic properties of these nanostructures in such a way as to exclude any mechanical displacement of the sample. Although there exist plenty of methods and devices for studying magnetic properties of materials, the development of novel schemes based on the known techniques for examining properties of magnetic nanomaterials, for example magnetic nanopowders, is a hot problem. The measurement equipment of the sort will detect changes in the magnetic properties of materials over time and under the influence of various factors, such as temperature, external magnetic fields, stabilizing substances.

Method and Methodology. The developed setup for registering magnetic hysteresis loops is based on the method of small perturbations performed by an alternating magnetic field. The devised scheme combines conventional physical principles of both hysterometers and vibrating-sample magnetometers.

Results. With the aid of the developed setup, magnetic hysteresis loops of  La_0.775Sr_0.225MnO₃ nanopowder have been obtained and compared with the data provided by the well-known technique. A good agreement was observed. The measurement error was 10%.

Conclusion. The suggested scheme can be used for the express registration of magnetic hysteresis loops of miscellaneous magnetic materials of various compositions, including nanoscale magnets.

Keywords: string magnetometer, magnetic hysteresis loop, magnetic nanoparticles, magnetization

Manuscript submitted 20.12.2021

Radio phys. radio astron. 2022, 27(1): 048-052

REFERENCES

1. Chechernikov, V.I., 1969. Magnetic measurements. 2nd ed. Ye.I. Kondorskii ed. Moscow: University publishing center (in Russian).

2. Maksimochkin, I., Trukhin, V.I., Garifullin, N.M., Khasanov, N.A., 2003. An Automated High-Sensitivity Vibrating-Coil Magnetometer. Instrum. Exp. Tech., 46(5), pp. 702-707. DOI: https://doi.org/10.1023/A:1026062310118

3. Shin, K.H., Park, K.I., Kim, Y., Sa-Gong, G., 2004. Vibrating sample magnetometer using a multilayer piezoelectric actuator. Phys. Status Solidi B, 241(7), pp. 1633-1636. DOI: https://doi.org/10.1002/pssb.200304666

4. Timofeev, V.P., Khvostov, S.S., Tsoi, G.M., Shny, V.I., 1992. UHF SQUID-magnetometer at 77 K. Cryogenics (Supplement ICEC 14 Proceedings), 32, pp. 517-520. DOI: https://doi.org/10.1016/0011-2275(92)90219-Z

5. He, D.F., Yoshizawa, M., 2003. Mobile high-Tc DC SQUID magnetometer. Physica B, 329-333, pp. 1489-1490. DOI: https://doi.org/10.1016/S0921-4526(02)02403-1

6. Lopez-Dominguez, V., Quesada, A., Guzmán-Mínguez, J.C., Moreno, L., Lere, M., Spottorno, J., Giacomone, F., Fernández, J.F., Hernando, A., García, M.A., 2018. A simple vibrating sample magnetometer for macroscopic samples. Rev. Sci. Instrum., 89(3), pp. 034707 (6 p.). DOI: https://doi.org/10.1063/1.5017708

7. Rubakhin, L.B., Rubakhin, V.B., 1976. String magnetometer. USSR Pat. 509849 (in Russian).

8. Rubakhin, L.B., Rubakhin, V.B., 1979. String magnetometer. USSR Pat. 664128 (in Russian).

9. Panfi lov, А.S., Pushkar, Yu.Ya., 1998. Experimental methods for studying the dependence of the magnetic susceptibility of solids on the atomic volume. Fizika i tekhnika vysokikh davleniy, 8(3), pp. 5-28 (in Russian).

10. Poole, C., 1997. Electron Spin Resonance: A comprehensive treatise on experimental techniques. New York: Dover Publ.

11. Gurevich, A.G., Melkov, G.A., 1996. Magnetization Oscillations and Waves. Boca Raton, N.Y., L., Tokyo: CRC Press.

12. Landau, L.D., Lifshits, E.M., 1987. Th eory of Elasticity. Moscow: Nauka Publ. (Vol. VII) (in Russian).

13. Shlapa, Yu.Yu., Solopan, S.A., Belous, A.G., 2018. Magnetothermic Eff ect in Core/Shell Nanocomposite (La,Sr)MnO3/SiO2. Th eor. Exp. Chem., 54(2), pp. 1-7. DOI: https://doi.org/10.1007/s11237-018-9551-0