MEASUREMENTS OF HYSTERESIS LOOPS OF THE MICROWIRES FIXED IN STRETCHED STATE USING THE VIBRATION MAGNETOMETRY

We present a technique of measuring hysteresis loops of the amorphous microwires using a method of vibrating-sample magnetometry. Control magnetic measurements were carried out on samples of an amorphous microwire of Fe₇₅B₁₃Si₁₀C2 composition in a glass shell obtained by the Ulitovsky – Taylor method. The sample was fixed on a specially manufactured experimental setup which enables us to stretch the microwire by means of suspended loads. Fixation of the microwire in the stretched state was carried out by the glue. The stresses in the metal core of the microwire formed upon stretching with suspended loads, as well as the stresses in the contact area of the wire and glue are calculated. The developed method provides fixing of tensile stresses in wires even when the value of stresses may attains a few GPa.

1. Vazquez M., Gomez-Polo C., Chen D.-X., Hernando A. Magnetic bistability of amorphous wires and sensor applications / IEEE Transactions on Magnetics. 1994. Vol. 30. P. 907 – 912.

2. Vazquez M., Zhukov A., Pirota K., Varga R., García K., Luna C., Provencio M., Navas D., Martínez J., Hernández-Vélez M. Temperature dependence of remagnetization process in bistable magnetic microwires / Journal of Non-Crystalline Solids. 2003. Vol. 329. P. 123 – 130.

3. Zhukova V., Aliev A., Varga R., Aronin A., Abrosimova G., Kiselev A., Zhukov A. Magnetic properties and MCE in Heusler-type glass-coated microwires / J. Supercond. Nov. Magn. 2013. Vol. 26. P. 1415 – 1419.

4. Vazquez M., Andenote-Engelvin A.-L. Glass-coated amorphous ferromagnetic microwires at microwave frequencies / Journal of Magnetism and Magnetic Materials. 2009. Vol. 321. P. 2066 – 2073.

5. Mohry K., Humphrey F., Kawashima K., Kimura K., Mizutani M. Large Barkhausen and Matteucci effects in FeCoSiB, FeCrSiB and FeNiSiB amorphous wires / IEEE Transactions on Magnetics. 1990. Vol. 26. P. 1789 – 1791.

6. Mohri K., Panina L. Magneto-impedance effect in amorphous wires / Appl. Phys. Lett. 1994. Vol. 65. P. 1189 – 1991.

7. Beach R. S., Berkowitz A. E. Giant magnetic field dependent impedance of amorphous FeCoSiB wire / Appl. Phys Lett. 1994. Vol. 64. P. 3652 – 3654.

8. Gonzalez J., Chen A., Blanco J., Zhukov A. Effect of applied mechanical stresses on the impedance response in amorphous microwires with vanishing magnetostriction / Phys. Stat. Sol. 2002. Vol. 189. P. 599 – 608.

9. Richter K., Kostyk Y., Varga R. Domain Wall Dynamics in Amorphous Microwires / Acta Physica Polonica A. 2008. Vol. 113. P. 7 – 10.

10. Kabanov Yu., Zhukov A., Zhukova V., Gonzalez J. Magnetic domain structure of microwires studied by using the magneto-optical indicator film method / Appl. Phys. Let. 2005. Vol. 87. P. 142507.

11. Chiriac H., Ovari T.-A., Yamasaki J., Zhukov A. Domain structure of ‘Thick’ amorphous microwire with nearly zero magnetostriction / Mat. Res. Soc. Symp. Proc. 2001. Vol. 674. P. U. 7. 7. 1 – U. 7. 7. 6.

12. Orlova N. N., Aronin A. S., Bozhko S. I., Kabanov Yu. P., Gornakov V. S. Magnetic structure and magnetization process of the glass-coated Fe-based amorphous microwire / Journal of Applied Physics. 2012. Vol. 111. P. 073906.

13. Orlova N. N., Gornakov V. S., Aronin A. S. Role of internal stresses in the formation of magnetic structure and magnetic properties of iron-based glass coated microwires / Journal of Applied Physics. 2017. Vol. 121. P. 205108.

14. Abrosimova G., Aronin A., Kir’janov Yu., Matveev D., Zver’kova I., Molokanov V., Pan S., Slipenyuk A. The structure and mechanical properties of bulk Zr50Ti16.5Cu14Ni18.5 metallic glass / J. Mater. Sci. 2001. Vol. 36. P. 3933 – 3939.

15. Abrosimova G., Aronin A., Matveev D., Pershina E. Nanocrystal formation, structure and magnetic properties of Fe-Si-B amorphous alloy after deformation / Materials Letters. 2013. Vol. 97. P. 15 – 17.

16. Chiriac H., Ovari T. A., Pop G. Internal stress distribution in glass-covered amorphous magnetic wires / Phys. Rev. B. 1995. Vol. 52. P. 10104 – 10113.

17. Darkov A. V., Shapiro G. S. Soprotivlenie materialov. — Moscow: Vysshaya shkola, 1975. — 654 p. [in Russian].

18. Inoue A., Chen H. S., Krause J. T., Masumoto T., Hag-iwara M. Young’s modulus of Fe-, Co-, Pd- and Pt-based amorphous wires produced by the in-rotating-water spinning method / Journal of Material Science. 1983. Vol. 18. P. 2743 – 2751.

19. http://forprof.ru/catalog/sekundnye-cianoakrilatnye-klei-super- moment/sekundnyy-tsianoakrilatnyy-kley-super-moment-gel-3-g-na-edinichnom-blistere (accessed 1.10.2017).