Two-Dimensional Periodic Composite Structure for Acoustic Sensor of Volumetric Properties of Liquids
https://doi.org/10.32603/1993-8985-2018-21-1-56-63
Abstract
The object of the study is acoustic metamaterial, which is a steel matrix with a periodic two-dimensional system of cylindrical cavities filled with hydrocarbon mixture. The induced resonances of fluid in cylindrical cavities of the periodic structure are studied for application in liquid fuel sensors. Theoretical studies of the structure show the possibility of exciting axisymmetric and spinning resonance modes in it in the frequency range with a high reflection coefficient of the structure, which manifest themselves as windows with a narrow bandwidth. Experimental studies confirm the existence of such resonances, and the asymmetric resonance mode is more evident. Measurements of various mixtures of gasoline and ethanol show that the sensor has significant sensitivity for distinguishing between conventional fuels, gasoline-based mixtures and the presence of additives in standard fuels.
About the Authors
N. V. Mukhin
Saint Petersburg Electrotechnical University "LETI".
Russian Federation
Nikolay V. Mukhin – Ph.D. in Engineering (2013), Associate Professor of the Department of Quantum Electronic and Optics Electronic Devices.The author of more than 50 scientific publications.Area of expertise: study of physicochemical and photoelectric properties of thin-film heterophase ferroelectric-semiconductor systems, development of photonic and phonon metamaterials. 5, Professor Popov Str, 197376, St. Petersburg.
Russian Federation
Nikolay V. Mukhin – Ph.D. in Engineering (2013), Associate Professor of the Department of Quantum Electronic and Optics Electronic Devices.The author of more than 50 scientific publications.Area of expertise: study of physicochemical and photoelectric properties of thin-film heterophase ferroelectric-semiconductor systems, development of photonic and phonon metamaterials. 5, Professor Popov Str, 197376, St. Petersburg.
D. N. Redka
Saint Petersburg Electrotechnical University "LETI".
Russian Federation
Dmitry N. Red'ka – Ph.D. in Engineering (2016), Assistant of the Department of Quantum Electronic and Optics Electronic Devices.The author of more than 20 scientific publications.Area of expertise: materials for solar energy, laser technology. 5, Professor Popov Str, 197376, St. Petersburg.
Russian Federation
Dmitry N. Red'ka – Ph.D. in Engineering (2016), Assistant of the Department of Quantum Electronic and Optics Electronic Devices.The author of more than 20 scientific publications.Area of expertise: materials for solar energy, laser technology. 5, Professor Popov Str, 197376, St. Petersburg.
S. A. Tarasov
Saint Petersburg Electrotechnical University "LETI".
Russian Federation
Russian Federation
Sergey A. Tarasov – D.Sc. in Engineering (2016), Chief of the Department of Quantum Electronic and Optics Electronic Devices.
The author of 91 scientific publications.
Area of expertise: organic photonics, LED technology, photoelectronics, devices based on quantum-based optoelectronics nanostructures.
5, Professor Popov Str, 197376, St. Petersburg.
A. Yu. Oseev
Otto von Guericke University Magdeburg.
Germany
Germany
Aleksandr Yu. Oseev – Ph.D. (2017), Researcher of the Department of Sensorics of Institute of Micro and Sensor Systems (IMOS), Otto von Guericke University Magdeburg, Germany.
The author of 24 scientific publications.
Area of expertise: fluidic sensors, more specifically, phononic crystal based sensors, microacoustic sensors, microfluidic sensor platforms, development of novel Lab-on-a-Chip microfluidic sensor concepts for miniaturised biomedical and industrial applications.
2, Universitätsplatz, Magdeburg, Deutschland, 39106.
S. Hirsch
Brandenburg University of Applied Sciences, Germany.
Germany
Germany
Soeren Hirsch – Ph.D. (2006), Professor of the University of Applied Science, Brandenburg.
The author of 68 scientific publications.
Area of expertise: silicon based microsystems and new packaging technologies.
50, Magdeburger Str., Brandenburg an der Havel, Deutschland, 14770.
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Review
For citations:
Mukhin N.V., Redka D.N., Tarasov S.A., Oseev A.Yu., Hirsch S. Two-Dimensional Periodic Composite Structure for Acoustic Sensor of Volumetric Properties of Liquids. Journal of the Russian Universities. Radioelectronics. 2018;(1):56-63. (In Russ.) https://doi.org/10.32603/1993-8985-2018-21-1-56-63
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