Studies of sensitivity of samples of nanocomposite materials based on opal matrices to magnetic fields

Authors

  • Борис Васильевич Хлопов FGUP «CNIRTI im. akademika A.I.Berga» Novaja Basmannaja st., 20, Moscow, Russia, 105066, Russian Federation https://orcid.org/0000-0002-9055-7464
  • Александр Васильевич Шпак FGUP «CNIRTI im. akademika A.I.Berga» Novaja Basmannaja st., 20, Moscow, Russia, 105066, Russian Federation https://orcid.org/0000-0001-9829-696X
  • Ярослав Дмитриевич Ковалюк FGUP «CNIRTI im. akademika A.I.Berga» Novaja Basmannaja st., 20, Moscow, Russia, 105066, Russian Federation https://orcid.org/0000-0001-7833-2265

DOI:

https://doi.org/10.15587/1729-4061.2015.37191

Keywords:

metamaterials, equipment, nanocomposites, opal matrix, multiplizieren, electromagnetic fields, precursor, metal cluster, erasing of information

Abstract

The properties of samples of metamaterials based on opal matrices with filling their nanoporosities by clusters of different magnetic and non-magnetic metal or magnetic crystallites were investigated.    

A method for assessing susceptibility of the developed composite materials to magnetic fields when exposed to external electromagnetic fields was developed. Designed and manufactured process equipment, consisting of the field-forming system, power generator, power source, throttle cooling system and certified and calibrated measuring instruments is shown.

Experimental results of the external electromagnetic field exposure on metamaterials as nanocomposites, representing discrete nanostructured environment with obtaining substantial electric “response”, in turn, leading, in particular, to the multiplication effect for applied electromagnetic fields in the field-forming system of the process test equipment at frequencies below 1010 kHz are given. It was experimentally confirmed that the values of the magnetic field parameters in the field-forming system of process test equipment change in the frequency range of up to 1010 kHz. Experimental characteristics of spatial multiplication of magnetic fields in the layout area of composite materials when exposed to external electromagnetic fields are provided. It was found and experimentally confirmed that external electromagnetic field exposure on nanocomposite samples in a limited space of the working chamber of the field-forming system leads to an effective increase in the magnetic field value in the local region of the spatial volume of up to 120 kA/m.

Author Biographies

Борис Васильевич Хлопов, FGUP «CNIRTI im. akademika A.I.Berga» Novaja Basmannaja st., 20, Moscow, Russia, 105066

Doctor of Technical Sciences, associate professor, the head of department

Александр Васильевич Шпак, FGUP «CNIRTI im. akademika A.I.Berga» Novaja Basmannaja st., 20, Moscow, Russia, 105066

Doctor of Technical Sciences

Department

Ярослав Дмитриевич Ковалюк, FGUP «CNIRTI im. akademika A.I.Berga» Novaja Basmannaja st., 20, Moscow, Russia, 105066

associate professor, the head of department

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Published

2015-02-26

How to Cite

Хлопов, Б. В., Шпак, А. В., & Ковалюк, Я. Д. (2015). Studies of sensitivity of samples of nanocomposite materials based on opal matrices to magnetic fields. Eastern-European Journal of Enterprise Technologies, 1(5(73), 54–60. https://doi.org/10.15587/1729-4061.2015.37191

Issue

Vol. 1 No. 5(73) (2015): Applied physics. Materials Science

Section

Materials Science

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Copyright (c) 2015 Борис Васильевич Хлопов, Александр Васильевич Шпак, Ярослав Дмитриевич Ковалюк

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