Adaptive Micromixer Based on the Solutocapillary Marangoni Effect in a Continuous-Flow Microreactor

Bratsun, Dmitry; Kostarev, K. G.; Мизев, А. И.; Aland, Sebastian; Mokbel, Marcel; Schwarzenberger, Karin; Eckert, Kerstin

doi:10.3390/mi9110600

Cited by 21 publications

(15 citation statements)

References 39 publications

(52 reference statements)

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“…2012), various biophysical lab-on-chip diagnostic systems (Ju & Warrick 2013; Sinz, Hanyak & Darhuber 2013; Yamada & Ono 2015) and continuous-flow microreactors (Nieves-Remacha, Kulkarni & Jensen 2012; Bratsun et al. 2018). The characteristic size of these devices, which is usually of the order of one millimetre or less, defines spatial scales for mass transfer processes.…”

Section: Introductionmentioning

confidence: 99%

“…The last decade has been marked by a rapidly increasing interest in techniques for manipulation of single phase inclusions (droplets, bubbles or particles) in a liquid phase. These techniques are promising, first of all, from the viewpoint of numerous chemical and biophysical applications among which the most important are microfluidic devices for the production of emulsions (Song, Tice & Ismagilov 2003;Seemann et al 2012), various biophysical lab-on-chip diagnostic systems (Ju & Warrick 2013;Sinz, Hanyak & Darhuber 2013;Yamada & Ono 2015) and continuous-flow microreactors (Nieves-Remacha, Kulkarni & Jensen 2012;Bratsun et al 2018). The characteristic size of these devices, which is usually of the order of one millimetre or less, defines spatial scales for mass transfer processes.…”

Section: Introductionmentioning

confidence: 99%

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Phase transitions on partially contaminated surface under the influence of thermocapillary flow

et al. 2019

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We study, both experimentally and theoretically, the fluid flow driven by a thermocapillary effect applied to a partially contaminated interface in a two-dimensional slot of finite extent. The contamination is due to the presence of an insoluble surfactant which is convected by the flow forming a stagnant zone by the colder edge of the interface. The thermocapillary surface stress is produced by a special optocapillary system, which makes it possible, first, to get an almost linear temperature profile along the interface and, second, to apply a surface pressure large enough to force the surfactant to experience a phase transition to a more condensed state. This enabled us for the first time since the release of the paper by Carpenter & Homsy (J. Fluid Mech., vol. 155, 1985, pp. 429–439) to test experimentally their theoretical predictions and obtain new results for the case when the contamination exists simultaneously in two phase states within the interface. We show that one part of the surface is free of surfactant and subject to vigorous thermocapillary flow, while another part is stagnant and subject to creeping flow with a surface velocity which is approximately two orders of magnitude smaller. We found that the extent of the stagnant zone theoretically predicted earlier does not coincide with the newly obtained experimental data. In this paper, we suggest analytical and numerical solutions for the position of the edge of the stagnation zone, which are in perfect agreement with the experimental data.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Phase transitions on partially contaminated surface under the influence of thermocapillary flow

et al. 2019

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“…2003), combustion processes (Zeldovich & Kompaneets 1960), separation of uranium ore (Thomson, Batey & Watson 1984), chemical reactor design and technology (Levich, Brodskii & Pismen 1967; Jakobsen 2008), external control of continuous-flow microreactors (Jensen 2001; Bratsun et al. 2018; Bratsun & Siraev 2020), chemisorption (Lambert 1997; Karlov et al. 2007), etc.…”

Section: Introductionmentioning

confidence: 99%

“…Although the chemo-hydrodynamic pattern formation in a system of two reacting fluids was experimentally observed as early as 1888 (Quincke 1888), these studies were mainly descriptive by nature due to the complexity of these processes. However, a really consistent detailed study of the reaction-diffusion processes coupled with hydrodynamic phenomena started only a century later, since it was stimulated by many important technological applications including oil refining (Dupeyrat & Nakache 1978), photochemical polymerization (Evans & Uri 1949;Belk et al 2003), combustion processes (Zeldovich & Kompaneets 1960), separation of uranium ore (Thomson, Batey & Watson 1984), chemical reactor design and technology (Levich, Brodskii & Pismen 1967;Jakobsen 2008), external control of continuous-flow microreactors (Jensen 2001;Bratsun et al 2018;Bratsun & Siraev 2020), chemisorption (Lambert 1997;Karlov et al 2007), etc. Starting with the monograph (Levich 1962), the interaction between reaction-diffusion phenomena and hydrodynamic instabilities has attracted increasing interest because chemically induced changes of fluid properties, such as concentration, density, viscosity and surface tension, may result in the instabilities, which exhibit a large variety of convective patterns.…”

Section: Introductionmentioning

confidence: 99%

Extended classification of the buoyancy-driven flows induced by a neutralization reaction in miscible fluids. Part 1. Experimental study

2021

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“…At present, there are several examples of well-developed technologies based on the CFMR/AFMR for the production of pharmaceutical substances by the method of continuous-flow synthesis [9][10][11]13]. In the last few years, different types of convective micromixers for the AFMR unit have been proposed [13][14][15]. Furthermore, various techniques have been developed for mixing typically laminar flows in the CFMR.…”

Section: Introductionmentioning

confidence: 99%

Switching Modes of Mixing Due to an Adjustable Gap in a Continuous-Flow Microreactor

Bratsun

Siraev

2019

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Microreactors are an important development in chemical engineering since the pharmaceutical industry needs flexible production rather than a large amount of product yield. The size of the microreactor may be so small that it requires the development of non-mechanical methods for reagent mixing. In this paper, we propose the design of a continuous-flow microreactor in the form of a narrow cell with a variable gap. By tuning the gap width in time and space, one can control the reaction rate and regulate the product yield. We show that the governing equation for the fluid flow can be reduced to the Darcy equation with permeability varying in space and time. As a test reaction, we consider the neutralization of nitric acid with sodium hydroxide resulting in the solutal convection in the presence of gravity. We show numerically that the prototyping spatially-distributed relief of the reactor walls can successfully separate the incoming and outgoing flows of reagents, control the mixing intensity, increase or decrease the product yield. We demonstrate also the dynamic control of the reactor efficiency via real-time local changes in the gap width.

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Adaptive Micromixer Based on the Solutocapillary Marangoni Effect in a Continuous-Flow Microreactor

Cited by 21 publications

References 39 publications

Phase transitions on partially contaminated surface under the influence of thermocapillary flow

Phase transitions on partially contaminated surface under the influence of thermocapillary flow

Extended classification of the buoyancy-driven flows induced by a neutralization reaction in miscible fluids. Part 1. Experimental study

Switching Modes of Mixing Due to an Adjustable Gap in a Continuous-Flow Microreactor

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