A new radio-frequency acoustic method for remote study of liquids

Abstract In the present work, a novel study method of conductive liquids has been proposed. It is based on a discovered phenomenon of radiofrequency anisotropy of electrolyte solution, which arises in response to mechanical excitation of the solution. The phenomenon was observed during the developme...

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Autores principales: Alexander V. Kramarenko, Andrey V. Kramarenko, Oksana Savenko
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Lenguaje:EN
Publicado: Nature Portfolio 2021
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Acceso en línea:https://doaj.org/article/2bd1f70613dc443d8306a45204937c94
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spelling oai:doaj.org-article:2bd1f70613dc443d8306a45204937c942021-12-02T11:45:02ZA new radio-frequency acoustic method for remote study of liquids10.1038/s41598-021-84500-62045-2322https://doaj.org/article/2bd1f70613dc443d8306a45204937c942021-03-01T00:00:00Zhttps://doi.org/10.1038/s41598-021-84500-6https://doaj.org/toc/2045-2322Abstract In the present work, a novel study method of conductive liquids has been proposed. It is based on a discovered phenomenon of radiofrequency anisotropy of electrolyte solution, which arises in response to mechanical excitation of the solution. The phenomenon was observed during the development of a radiofrequency polarimetric contactless cardiograph. The electric field vector rotates after its transition through the pericardial region due to the acceleration changes of blood. Numerous in vitro experiments with monochromatic and impulse acoustic waves always induced the polarization rotation of the RF wave passing through an electrolyte solution. The response obtained from the solutions on acoustic excitation of the Heaviside function form demonstrates the effect of a solution “memory”. The dynamics of this process resembles the spin glasses magnetization. We hypothesized that there was a magnetic moment change within the solution, and the possible reason for it is an appearance of electromagnetic impulse caused by the same acoustic excitation. In a further experiment, we really captured a suspected electrical potential. Given that, we can declare at least three new physical effects never observed before for an electrolyte solution. The study method itself may provide broad options for remote measurement of the electrolyte solution parameters.Alexander V. KramarenkoAndrey V. KramarenkoOksana SavenkoNature PortfolioarticleMedicineRScienceQENScientific Reports, Vol 11, Iss 1, Pp 1-11 (2021)
institution DOAJ
collection DOAJ
language EN
topic Medicine
R
Science
Q
spellingShingle Medicine
R
Science
Q
Alexander V. Kramarenko
Andrey V. Kramarenko
Oksana Savenko
A new radio-frequency acoustic method for remote study of liquids
description Abstract In the present work, a novel study method of conductive liquids has been proposed. It is based on a discovered phenomenon of radiofrequency anisotropy of electrolyte solution, which arises in response to mechanical excitation of the solution. The phenomenon was observed during the development of a radiofrequency polarimetric contactless cardiograph. The electric field vector rotates after its transition through the pericardial region due to the acceleration changes of blood. Numerous in vitro experiments with monochromatic and impulse acoustic waves always induced the polarization rotation of the RF wave passing through an electrolyte solution. The response obtained from the solutions on acoustic excitation of the Heaviside function form demonstrates the effect of a solution “memory”. The dynamics of this process resembles the spin glasses magnetization. We hypothesized that there was a magnetic moment change within the solution, and the possible reason for it is an appearance of electromagnetic impulse caused by the same acoustic excitation. In a further experiment, we really captured a suspected electrical potential. Given that, we can declare at least three new physical effects never observed before for an electrolyte solution. The study method itself may provide broad options for remote measurement of the electrolyte solution parameters.
format article
author Alexander V. Kramarenko
Andrey V. Kramarenko
Oksana Savenko
author_facet Alexander V. Kramarenko
Andrey V. Kramarenko
Oksana Savenko
author_sort Alexander V. Kramarenko
title A new radio-frequency acoustic method for remote study of liquids
title_short A new radio-frequency acoustic method for remote study of liquids
title_full A new radio-frequency acoustic method for remote study of liquids
title_fullStr A new radio-frequency acoustic method for remote study of liquids
title_full_unstemmed A new radio-frequency acoustic method for remote study of liquids
title_sort new radio-frequency acoustic method for remote study of liquids
publisher Nature Portfolio
publishDate 2021
url https://doaj.org/article/2bd1f70613dc443d8306a45204937c94
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