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Influence of the gas–liquid non-equilibrium media structure on the mass transfer dynamics in biophysical processes. / Nizovtseva, Irina; Starodumov, Ilya; Lezhnin, Sergey et al.
In: Smart Materials and Structures, Vol. 33, No. 1, 015028, 2024.

Research output: Contribution to journalArticlepeer-review

Harvard

Nizovtseva, I, Starodumov, I, Lezhnin, S, Mikushin, P, Zagoruiko, A, Shabadrov, P, Svitich, V, Vikharev, S, Tatarintsev, VV, Nikishina, M, Koroznikova, I, Glebova, A, Mityashin, T, Jingyan, Y & Chernushkin, D 2024, 'Influence of the gas–liquid non-equilibrium media structure on the mass transfer dynamics in biophysical processes', Smart Materials and Structures, vol. 33, no. 1, 015028. https://doi.org/10.1088/1361-665X/ad10be

APA

Nizovtseva, I., Starodumov, I., Lezhnin, S., Mikushin, P., Zagoruiko, A., Shabadrov, P., Svitich, V., Vikharev, S., Tatarintsev, V. V., Nikishina, M., Koroznikova, I., Glebova, A., Mityashin, T., Jingyan, Y., & Chernushkin, D. (2024). Influence of the gas–liquid non-equilibrium media structure on the mass transfer dynamics in biophysical processes. Smart Materials and Structures, 33(1), [015028]. https://doi.org/10.1088/1361-665X/ad10be

Vancouver

Nizovtseva I, Starodumov I, Lezhnin S, Mikushin P, Zagoruiko A, Shabadrov P et al. Influence of the gas–liquid non-equilibrium media structure on the mass transfer dynamics in biophysical processes. Smart Materials and Structures. 2024;33(1):015028. doi: 10.1088/1361-665X/ad10be

Author

Nizovtseva, Irina ; Starodumov, Ilya ; Lezhnin, Sergey et al. / Influence of the gas–liquid non-equilibrium media structure on the mass transfer dynamics in biophysical processes. In: Smart Materials and Structures. 2024 ; Vol. 33, No. 1.

BibTeX

@article{35ad143647eb4d43854d0880c90cfa1a,
title = "Influence of the gas–liquid non-equilibrium media structure on the mass transfer dynamics in biophysical processes",
abstract = "Multiphase biophysical media are known to be complex structures with continuous high demand to the scientific community for understanding the relationships and ratios between factors affecting the type, dynamics and nature of its structural changes on their impact degree on the media itself. Among the plentiful list of such factors the following do worth mentioning: the lifetime of a particle, turbulence factors and a number of others, each requiring careful analysis, assessment of the contribution degree and, importantly, correct accounting. The present study is focused on such a factor affecting mass transfer intensity change as surface tension through its relationship with the interfacial area: the latter is the site of mass exchange between the gas and liquid phases, and modifications in surface tension values can significantly impact the characteristics of this area, hence altering the rate of mass transfer. By controlling surface tension, one can effectively modulate the size and stability of particles, namely bubbles or droplets, which in turn changes the interfacial area available for mass transfer. The total interfacial area, which is the cumulative surface area of all bubbles, serves as the site for mass transfer. The impact of the surface tension coefficient variation into gas–liquid mass transfer characteristics is analyzed both for the case of water and model liquid. The latter means the potential contribution of surface-active substances was a part of research scope since it was applied to recreate conditions similar to the cultural liquid when microorganisms that produce surfactants are grown. The proposed new methodology assumes calculating interfacial area through the segmentation of images captured by a high-speed camera, thus we can gain a profoundly enhanced understanding of the relationship between surface tension and mass transfer. The precise visual data and subsequent computation of the interfacial area provide deeper insights into the dynamics of bubble formation and the effects of surface tension on bubble size and distribution. As a result, this method has significantly improved our capacity to investigate and optimize mass transfer processes in multiphase biophysical systems. Both analytical approach and results interpretation not only influence affirmatively on deep understanding of natural mechanisms in biophysical media, but also might serve their best for potential application, e.g. in the context of the development of biotechnological industries based on fermentation processes for protein production.",
author = "Irina Nizovtseva and Ilya Starodumov and Sergey Lezhnin and Pavel Mikushin and Andrey Zagoruiko and Pavel Shabadrov and Vladislav Svitich and Sergey Vikharev and Tatarintsev, {Vitalii V.} and Margarita Nikishina and Irina Koroznikova and Alexandra Glebova and Timofey Mityashin and Yang Jingyan and Dmitrii Chernushkin",
note = "The research funding from the Ministry of Science and Higher Education of the Russian Federation (Ural Federal University Program of Development within the Priority-2030 Program) is gratefully acknowledged.",
year = "2024",
doi = "10.1088/1361-665X/ad10be",
language = "English",
volume = "33",
journal = "Smart Materials and Structures",
issn = "0964-1726",
publisher = "Institute of Physics Publishing (IOP)",
number = "1",

}

RIS

TY - JOUR

T1 - Influence of the gas–liquid non-equilibrium media structure on the mass transfer dynamics in biophysical processes

AU - Nizovtseva, Irina

AU - Starodumov, Ilya

AU - Lezhnin, Sergey

AU - Mikushin, Pavel

AU - Zagoruiko, Andrey

AU - Shabadrov, Pavel

AU - Svitich, Vladislav

AU - Vikharev, Sergey

AU - Tatarintsev, Vitalii V.

AU - Nikishina, Margarita

AU - Koroznikova, Irina

AU - Glebova, Alexandra

AU - Mityashin, Timofey

AU - Jingyan, Yang

AU - Chernushkin, Dmitrii

N1 - The research funding from the Ministry of Science and Higher Education of the Russian Federation (Ural Federal University Program of Development within the Priority-2030 Program) is gratefully acknowledged.

PY - 2024

Y1 - 2024

N2 - Multiphase biophysical media are known to be complex structures with continuous high demand to the scientific community for understanding the relationships and ratios between factors affecting the type, dynamics and nature of its structural changes on their impact degree on the media itself. Among the plentiful list of such factors the following do worth mentioning: the lifetime of a particle, turbulence factors and a number of others, each requiring careful analysis, assessment of the contribution degree and, importantly, correct accounting. The present study is focused on such a factor affecting mass transfer intensity change as surface tension through its relationship with the interfacial area: the latter is the site of mass exchange between the gas and liquid phases, and modifications in surface tension values can significantly impact the characteristics of this area, hence altering the rate of mass transfer. By controlling surface tension, one can effectively modulate the size and stability of particles, namely bubbles or droplets, which in turn changes the interfacial area available for mass transfer. The total interfacial area, which is the cumulative surface area of all bubbles, serves as the site for mass transfer. The impact of the surface tension coefficient variation into gas–liquid mass transfer characteristics is analyzed both for the case of water and model liquid. The latter means the potential contribution of surface-active substances was a part of research scope since it was applied to recreate conditions similar to the cultural liquid when microorganisms that produce surfactants are grown. The proposed new methodology assumes calculating interfacial area through the segmentation of images captured by a high-speed camera, thus we can gain a profoundly enhanced understanding of the relationship between surface tension and mass transfer. The precise visual data and subsequent computation of the interfacial area provide deeper insights into the dynamics of bubble formation and the effects of surface tension on bubble size and distribution. As a result, this method has significantly improved our capacity to investigate and optimize mass transfer processes in multiphase biophysical systems. Both analytical approach and results interpretation not only influence affirmatively on deep understanding of natural mechanisms in biophysical media, but also might serve their best for potential application, e.g. in the context of the development of biotechnological industries based on fermentation processes for protein production.

AB - Multiphase biophysical media are known to be complex structures with continuous high demand to the scientific community for understanding the relationships and ratios between factors affecting the type, dynamics and nature of its structural changes on their impact degree on the media itself. Among the plentiful list of such factors the following do worth mentioning: the lifetime of a particle, turbulence factors and a number of others, each requiring careful analysis, assessment of the contribution degree and, importantly, correct accounting. The present study is focused on such a factor affecting mass transfer intensity change as surface tension through its relationship with the interfacial area: the latter is the site of mass exchange between the gas and liquid phases, and modifications in surface tension values can significantly impact the characteristics of this area, hence altering the rate of mass transfer. By controlling surface tension, one can effectively modulate the size and stability of particles, namely bubbles or droplets, which in turn changes the interfacial area available for mass transfer. The total interfacial area, which is the cumulative surface area of all bubbles, serves as the site for mass transfer. The impact of the surface tension coefficient variation into gas–liquid mass transfer characteristics is analyzed both for the case of water and model liquid. The latter means the potential contribution of surface-active substances was a part of research scope since it was applied to recreate conditions similar to the cultural liquid when microorganisms that produce surfactants are grown. The proposed new methodology assumes calculating interfacial area through the segmentation of images captured by a high-speed camera, thus we can gain a profoundly enhanced understanding of the relationship between surface tension and mass transfer. The precise visual data and subsequent computation of the interfacial area provide deeper insights into the dynamics of bubble formation and the effects of surface tension on bubble size and distribution. As a result, this method has significantly improved our capacity to investigate and optimize mass transfer processes in multiphase biophysical systems. Both analytical approach and results interpretation not only influence affirmatively on deep understanding of natural mechanisms in biophysical media, but also might serve their best for potential application, e.g. in the context of the development of biotechnological industries based on fermentation processes for protein production.

UR - http://www.scopus.com/inward/record.url?partnerID=8YFLogxK&scp=85180536129

UR - https://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=tsmetrics&SrcApp=tsm_test&DestApp=WOS_CPL&DestLinkType=FullRecord&KeyUT=001126293300001

U2 - 10.1088/1361-665X/ad10be

DO - 10.1088/1361-665X/ad10be

M3 - Article

VL - 33

JO - Smart Materials and Structures

JF - Smart Materials and Structures

SN - 0964-1726

IS - 1

M1 - 015028

ER -

ID: 50637440