Thursday, September 5, 2019
Aqueous Magnetic Fluids Instabilities in a Hele-Shaw Cell
Aqueous Magnetic Fluids Instabilities in a Hele-Shaw Cell M. RÃâââ¬Å¡CUCIU ââ¬Å"Lucian Blagaâ⬠University, Faculty of Science, Dr.Ratiu Street, No.5-7, Sibiu, 550024, Romania In this study, it was investigated the interface patterns of two immiscible, viscous fluids into the geometry of a horizontalà Hele-Shaw cell, considering that one of the fluids is an aqueous magnetic fluid. In general, the total energy of a magnetic fluidà system consists of three components: gravitational, surface, and magnetic. For a magnetic fluid into a horizontal Hele-Shawà cell, the gravitational energy is constant and can be inessential, thus leaving only the surface and magnetic energies. Theà interface between two immiscible fluids, one of them with a low viscosity and another with a higher viscosity, becomesà unstable and starts to deform. Dynamic competition in such confined geometry leads finally to the formation of fingeringà patterns of a magnetic fluid in a Hele-Shaw cell. The computational study upon the interface instabilities patterns in aqueousà magnetic fluids was accomplished evaluating fractal dimension in finger-type instabilities. Between the fr actal dimension andà experimental instability generation time a correlation was established. (Received January 30, 2009; accepted February 13, 2009) Keywords: Magnetic fluid, Hele-Shaw cell, Viscous finger instability 1. Introduction Magnetic fluids are composed of magnetic, around 10à nm, single-domain particles coated with a molecularà surfactant and suspended in a carrier liquid [1]. Magneticà fluids confined within Hele-Shaw cell exhibit interestingà interfacial instabilities, like fingering instability. The patterns and shapes formation by diverse physical,à chemical and biological systems in the natural world hasà long been a source of fascination for scientists [2]. Interfaceà dynamics plays a major role in pattern formation. Viscousà fingering occurs in the flow of two immiscible, viscousà fluids between the plates of a Hele-Shaw cell. A magnetic fluid is considered paramagnetic becauseà the individual nanoparticle magnetizations are randomlyà oriented, even the solid magnetic nanoparticles areà ferromagnetic [3]. Due to Brownian motion, the thermalà agitation keeps the magnetic nanoparticles suspended andà the coating prevents the nanoparticles from adhering toà each other. In ionic magnetic fluids coating the magneticà nanoparticles are replaced one an other by electrostaticà repulsion. Because the magnetic nanoparticles are muchà smaller than the Hele-Shaw cell thickness, it may neglectà their particulate properties and it may consider a continuousà paramagnetic fluid. In this study, there was investigated the interfaceà patterns of two immiscible, viscous fluids into the geometryà of a horizontal Hele-Shaw cell, considering that one of theà fluids is an aqueous magnetic fluid. In general, the total energy of a magnetic fluid systemà consists of three components: gravitational, surface, andà magnetic. For a magnetic fluid into a horizontal Hele-Shawà cell, the gravitational energy is constant and can beà inessential, thus leaving only the surface and magneticà energies. The interface between two immiscible fluids, one ofà them with a low viscosity and another with a higherà viscosity, becomes unstable and starts to deform. Dynamicà competition in such confined geometry leads finally to theà formation of fingering patterns of a magnetic fluid in aà two-dimensional geometry (Hele-Shaw cell) [4-5]. Due to pressure gradients or gravity, the separationà interface of the two immiscible, viscous fluids undergoesà on to Saffman-Taylor instability [6] and developsà finger-like structures. The Saffman-Taylor instability is aà widely studied example of hydrodynamic pattern formationà where interfacial instabilities evolve. The computational study upon the interfaceà instabilities patterns in aqueous magnetic fluids was carriedà out by evaluating the fractal dimension in finger-typeà instabilities. 2. Experimental Aqueous magnetic fluids used in this study have beenà prepared in our laboratory, by applying the chemicalà precipitation method. In table I are presented the aqueousà magnetic fluid samples used in this experimental study. Table 1. The magnetic fluid samples used in this study (d ââ¬âà physical diameter of the magnetic nanoparticles,à constituents of the magnetic fluid samples). Aqueous magnetic fluids instabilities in a Hele-Shaw cell In this paper, it studies the interface between twoà immiscible fluids and with different viscosities, one ofà them with a low viscosity and with magnetic propertiesà (aqueous magnetic fluid) and another with a higherà viscosity and non-magnetic (65% aqueous glycerin), whenà the instability pattern diameter increased in time, instabilityà structure became more and more complex. The splitting ofà the main finger streamer was occurred in time, determiningà the irregularity increasing. For each instant image obtainedà was computed the fractal dimension. a less viscous fluid is injected into a more viscous one in aà 2D geometry (Hele Shaw cell). Fig. 1 shows a Hele-Shaw cell, used in this experiment,à with its two plates of plastic separated by cover microscopeà slides placed in each corner of the cell, having the sameà thickness about 300 micrometers. The used fluids areà injected through the center hole. Fig. 2. The finger instability dynamics for aqueousà magnetic liquid stabilized with citric acid (A2 sample). Between the fractal dimension and experimentalà instability generation time a linear correlations wereà established for all magnetic fluid samples used in this studyà (correlation coefficient, R2, 0.962). In Fig. 3 is presentedà the dynamics of the fractal dimension during the surfaceà image recording, for A1 magnetic fluid sample. Fig. 1. Hele- Shaw cell used in this experimental study. In the experiment firstly was injected aqueous glycerinà through the central hole to fill the cell. After the cell wasà filled with glycerin, the magnetic fluid was injected. Theà surface image recordings were made with a digital camera. The computational study upon the interfaceà instabilities patterns between aqueous magnetic fluids andà glycerin was accomplished evaluating fractal dimension inà finger-type instabilities. The fractal analysis was carried outà using the box-counting method [7] as a computationalà algorithm. In order to apply box-counting method theà surface images were analyzed following the HarFA 5.0à software steps, computing the fractal dimension of the eachà image. Fig. 3. The dynamics of the fractal dimension in the A1à magnetic fluid sampleà case, stabilized with 3. Results and discussion The computational study was accomplished on threeà sets of images, for aqueous magnetic fluids analyzed in thisà study, representing finger instabilities developed betweenà two immiscible fluids and with different viscosities. In Fig. 2 are presented the finger instability dynamicsà for aqueous magnetic liquid stabilized with citric acid (A2à sample), having a radial symmetry between the fluidsà injected in the Hele-Shaw cell (glycerin and magneticà fluid).From images shown in Fig. 2 it may be observed thatà tetrametilamoniu hydroxide. Also, between the fractal dimension and physicalà diameter of the magnetic nanoparticles, constituents of theà magnetic fluid sample, a correlation was established (aà linear regression with a correlation coefficient, R2 = 0.926). In Fig. 4 it may be observed that for increasing physicalà diameter of the magnetic nanoparticles was obtained aà decreased fractal dimension, after a flow time of magnetic fluids about 9 seconds. 134 Fig. 4. Graphical dependence of fractal dimension inà function of physical diameter of the magneticà nanoparticles, constituents of the magnetic fluid samplesà analyzed in this study. M. RÃâÃâcuciu within the Hele-Shaw cell about 7 seconds. In the Saffman-Taylor instability, if a forward bump isà formed on the interface between the fluids, it enhances theà pressure gradient and the local interface velocity. Becauseà the velocity of a point on the interface is proportional to theà local pressure gradient, the bump grows faster than otherà parts on the interface. On the other hand, the effect ofà surface tension competes with this diffusive instability. Surface tension operates to reduce the pressure at highlyà curved parts of an interface, and sharp bumps are forcedà back. Thus, as a result we have the formation of the viscousà finger instabilities. The fractal dimension based analysis proposed in thisà paper of the aqueous magnetic fluid instability is intendedà to lead to further mathematical modeling of fingerà instabilities patterns focused on non-linearity of theà magnetic fluid-non-magnetic fluid interface stability. A linear correlation (correlation coefficient, R2, 0.988)à was established between the fractal dimension andà viscosity value of the magnetic fluid samples used In Fig. 5à it may be observed that for increased viscosity value of theà magnetic fluid was observed increasing the fractalà dimension of the interface fluids instability structure. Fig. 5. Linear correlation between fractal dimension andà magnetic fluid viscosity value. Table 2. Correlation coefficient and standard deviation toà the fractal dimension calculation after a flow time ofà magnetic fluids within the Hele-Shaw cell about 7à seconds. 4. Conclusions In this paper it was investigated the flow of twoà immiscible, viscous fluids in the confined geometry of aà Hele-Shaw cell. It may conclude that the fractal dimension values of theà finger instabilities pattern images are direct proportionalà with the magnetic fluid viscosity value and instabilityà generation time, while with the physical diameter of theà magnetic nanoparticles constituents of the magnetic fluid aà linear negative dependence was evidenced. The next theoretical analysis step will follow theà developing of a convenient model to describe theà non-magnetic fluid influence on magnetic fluid surfaceà stability. References [1] P. S. Stevens, Patterns in Nature, Little Brown, Bostonà (1974). [2] S.S. Papel, Low viscosity magnetic fluid obtained byà the colloidal suspension of magnetic particles. USà Patent 3, 215, 572 (1965). [3] R. E. Rosensweig, Ferrohydrodynamics, Cambridgeà University Press, Cambridge (1985). [4] C. Tang, Rev. Mod. Phys., 58, 977 (1986). [5] D. Bensimon, L. P. Kadanoff, S. Liang, B. I. Shraiman,à C. Tang, Rev.Mod. Phys., 58, 977 (1986). [6] P. G. Saffman, G. I. Taylor, Proc. R. Soc. London, Ser.à A, 245, 312 (1958). [7] T. Tel, A. Fulop, T. Vicsek, Determination of Fractalà Dimension for Geometrical Multifractals, Physica A,à 159, 155-166 (1989). ________________________ * In Table 2 the fractal dimension value, correlationà coefficient and standard deviation to the fractal dimensionà calculation, for all magnetic fluid samples used in this experimental study after a flow time of magnetic fluids
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