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Colloid and Polymer Science

Erschienen in:

27.02.2018 | Original Contribution

Electrophoresis of concentrated suspension of soft particles with volumetrically charged inner core

verfasst von: Saurabh Kumar Maurya, Partha P. Gopmandal, H. Ohshima

Erschienen in: Colloid and Polymer Science | Ausgabe 4/2018

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Abstract

The present study deals with the electrophoresis of a concentrated suspension of soft particles. The inner core of the undertaken particles is considered to possess constant volumetric charges and is surrounded by an ion- and fluid-penetrable polyelectrolyte layer (PEL) with uniformly distributed immobile charges. Such types of particles are paradigm of several bio-particles, for example, virus, bacteria, yeasts, and humic substances, to name a few. A unit cell model is employed to take into account the effect of the interaction between neighboring particles. In the present study, we restrict ourselves with the low charge density and weak applied electric field assumptions. The electric potential distribution is obtained from the linearized Poisson-Boltzmann equation. The fluid velocity field inside the PEL and portion of the cell filled with electrolyte solution are determined by solving the Darcy-Brinkman and Stokes equations, respectively. We provide semi-analytical results for the mean electrophoretic mobility of the concentrated suspension of the undertaken soft particles. We have shown extensively that the suspension of the soft particles may switch its propulsion direction depending on the choice of the pertinent parameters. Unlike suspension of bare colloids or full porous particles, the mean electrophoretic mobility of the soft particles may be nonzero even at a net zero charge case.

Vorheriger Artikel Identification of thermal shear bands in a low molecular weight polymer melt under oscillatory strain field

Nächster Artikel On the fracture mechanism of a symmetric interface of glassy poly(methyl methacrylate) self-healed at a temperature well below the bulk glass transition temperature

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Reuss FF (1809) Sur un nouvel effet de le électricité glavanique. Mém Soc Impériale Naturalistes Moscou 2:327–337

von Smoluchowski M (1921) Elektrische endosmose und strömungsströme. In: Greatz E (ed) Handbuch der elektrizität und des magnetismus. Band II Stationȧre ströme, Barth, pp 366– 428

Hückel E. (1924) Die kataphorese der kugel. Phys Z 25:204–210

Henry D (1931) The cataphoresis of suspended particles. Part 1—the equation of cataphoresis. Proc Roy Soc A 133:106– 129CrossRef

Ohshima H (1997) Electrophoretic mobility of a polyelectrolyte-adsorbed particle: effect of segment density distribution. J Colloid Interface Sci 185:269–273CrossRef

Duval JFL, Wilkinson KJ, Van Leeuwen HP, Buffle JB (2005) Humic substances are soft and permeable: evidence from their electrophoretic mobilities. Environ Sci Technol 39:6435–6445CrossRef

Likos CN (2006) Soft matter with soft particles. Soft Matter 2:478–498CrossRef

Ohshima H (1994) Electrophoretic mobility of Soft particle. J Colloid Interface Sci 163:474–483CrossRef

Ohshima H (1995) Electroporesis of Soft particle. J Colloid Interface Sci 62:189–235CrossRef

10.

Ohshima H (2002) Modified Henry function for the electrophoretic mobility of a charged spherical colloidal particle covered with an ion-penetrable uncharged polymer layer. J Colloid Interface Sci 252:119–125CrossRef

11.

Ohshima H (2006) Electrophoresis of soft particles: analytic approximations. Electrophresis 27:526–533CrossRef

12.

Hill RJ, Saville DA, Russel WB (2003) Electrophoresis of spherical polymercoated colloidal particles. J Colloid Interface Sci 258:56–74CrossRef

13.

Hill RJ, Saville DA (2005) Exact solutions of the full electrokinetic model for soft spherical colloids: electrophoretic mobility. Colloids Surf A: Physicochem Eng Asp 267:31–49CrossRef

14.

Hsu J, Chen ZS, Tseng S (2009) Effect of electroosmotic flow on the electrophoresis of a membrane-coated sphere along the axis of a cylindrical pore. J Phys Chem B 113:7701–7708CrossRef

15.

Zhang XG, Hsu J, Chen ZS, Yeh LH, Ku MH, Tseng S (2010) Electrophoresis of a charge-regulated soft sphere in a charged cylindrical pore. J Phys Chem B 114:1621–1631CrossRef

16.

Yeh LS, Hsu J (2011) Effects of double-layer polarization and counterions condensation on the electrophoresis of polyelectrolytes. Soft Matter 7:396–411CrossRef

17.

Chou CH, Hsu J, Ohshima H, Tseng S, Wu RM (2012) Importance of the porous structure of a soft particle on its electrophoretic behavior. Colloids Surf B: Biointerfaces 93:154–160CrossRef

18.

Bhattacharyya S, Gopmandal PP (2013) Effects of electroosmosis and counterion penetration on electrophoresis of a positively charged spherical permeable particle. Soft Matter 9:1871–1884CrossRef

19.

Gopmandal PP, Bhattacharyya S (2014) Nonlinear effects on electrokinetics of a highly charged porous sphere. Colloid Polym Sci 292:905–914CrossRef

20.

Ghoshal G, Bhattacharyya S, Gopmandal PP, De S (2017) Nonlinear effects on electrophoresis of a soft particle and sustained solute release, transport of porous media. https://doi.org/10.1007/s11242-017-0952-7

21.

Ohshima H (2011) Electrophoretic mobility of a highly charged soft particle: relaxation effect. Colloids Surf A: Physicochem Eng. Asp 376:72–75CrossRef

22.

Ohshima H, Makino K, Kato T, Kondo T, Kawaguchi H (1993) Electrophoretic mobility of latex particles covered with temperature-sensitive hydrogel layers. J Colloid Interface Sci 159:512–514CrossRef

23.

Sonohara R, Muramatsu N, Ohshima H, Kondo T (1995) Difference in surface properties between Escherichia coli and Staphylococcus aureus as revealed by electrophoretic mobility measurements. Biophys Chem 5:273–277CrossRef

24.

López-Viota J, Mandal S, Delgado A, Toca-Herrera JL, Möller Marco ZF, Balestrino M, Krol S (2009) Electrophoretic characterization of gold nanoparticles functionalized with human serum albumin (HSA) and creatine. J Colloid Interface Sci 332:215– 223CrossRef

25.

Duval JFL, Gaboriaud F (2010) Progress in electrohydrodynamics of soft microbial particle interphases. Curr Opin Colloid Interface Sci 15:184–195CrossRef

26.

Nguyen TH, Easter N, Gutierrez L, Huyett L, Defnet E, Mylon SE, Ferrid JK, Viet N (2011) The RNA core weakly influences the interactions of the bacteriophage MS2 at key environmental interfaces. Soft Matter 7:10449–10456CrossRef

27.

Phan AD, Tracy DA, Nguyen TLH, Viet NA, Phan T, Nguyen TH (2013) J Chem Phys 139:244908–1-5

28.

McDaniel K, Valcius F, Andrews J, Das S (2015) Electrostatic potential distribution of a soft spherical particle with acharged core and pH-dependent charge density. Colloids Surf B: Biointerfaces 127:143–147CrossRef

29.

Gopmandal PP, Bhattacharyya S, Ohshima H (2016) Effect of core charge density on the electrophoresis of a soft particle coated with polyelectrolyte layer. Colloid Polym Sci 294:727–733CrossRef

30.

Gopmandal PP, Bhattacharyya S, Banerjee M, Ohshima H (2016) Electrophoresis of soft particles with charged rigid core coated with pH-regulated polyelectrolyte layer. Colloid Polym Sci 294:1845–1856CrossRef

31.

Gopmandal PP, Bhattacharyya S, Banerjee M, Ohshima H (2016) Electrophoresis of diffuse soft particles with dielectric charged rigid core grafted with charge regulated inhomogeneous polymer segments. Colloids Surf A: Physicochem Eng Asp 504:116–125CrossRef

32.

De S, Bhattacharyya S, Gopmandal PP (2016) Importance of core electrostatic properties on the electrophoresis of a soft particle. Phys Rev E 94:022611CrossRef

33.

Gopmandal PP, Ohshima H (2017) Importance of pH-regulated charge density on the electrophoresis of soft particles. Chem Phys 483-484:165–171CrossRef

34.

Ganjizade A, Nezameddin Ashrafizadeh S, Sadeghi A (2017) Effect of ion partitioning on the electrostatics of soft particles with a volumetrically charged core. Electrochem Commun 84:19–23CrossRef

35.

Ohshima H (2000) Electrophoretic mobility of soft particles in concentrated suspensions. J Colloid Interface Sci 225:233–242CrossRef

36.

Ohshima H (2000) Electrical conductivity of a concentrated suspension of soft particles. J Colloid Interface Sci 229:307–309CrossRef

37.

Lee E, Chou K-T, Hsu J-P (2004) Electrophoresis of a concentrated dispersion of spherical particles covered by an ion-penetrable membrane layer. J Colloid Interface Sci 280:518–526CrossRef

38.

Sagou JPS, Ahualli S, Thomas F (2015) Influence of ionic strength and polyelectrolyte concentration on the electrical conductivity of suspensions of soft colloidal polysaccharides. J Colloid Interface Sci 459:212–217CrossRef

39.

Huang HY, Keh HJ (2015) Electrophoretic mobility and electric conductivity in suspensionsof charge-regulating porous particles. Colloid Polym Sci 293:1903–1914CrossRef

40.

Kuwabara S (1959) The forces experienced by a lattice of elliptic cylinders in a uniform flow at small reynolds numbers. J Phys Soc Jpn 14:522–527CrossRef

41.

Landau LD, Lifshitz EM (1966) Fluid mechanics. Pergamon, London

42.

Yeh LH, Fang KY, Hsu J, Tseng S (2011) Influence of boundary on the effect of double-layer polarization and the electrophoretic behavior of soft biocolloids. Colloids Surf B: Biointerfaces 88:559–567CrossRef

43.

Ohshima H (2016) On the maximum of the magnitude of the electrophoretic mobility of a spherical colloidal particle in an electrolyte solution. Colloid Polym Sci 294:13–17CrossRef

44.

Sugioka H (2014) DC step response of induced-charge electro-osmosis between parallel electrodes at large voltages. Phys Rev E 90:013007CrossRef

45.

Stout RF, Khair AS (2014) A continuum approach to predicting electrophoretic mobility reversals. J Fluid Mech 752:R1–R12CrossRef

46.

Moussa M, Caillet C, Town RM, Duval JFL (2015) Remarkable electrokinetic features of charge-stratified soft nanoparticles: mobility reversal in monovalentaqueous electrolyte. Langmuir 31:5656–5666CrossRef

Titel: Electrophoresis of concentrated suspension of soft particles with volumetrically charged inner core
verfasst von: Saurabh Kumar Maurya
Partha P. Gopmandal
H. Ohshima
Publikationsdatum: 27.02.2018
Verlag: Springer Berlin Heidelberg
Erschienen in: Colloid and Polymer Science / Ausgabe 4/2018
Print ISSN: 0303-402X
Elektronische ISSN: 1435-1536
DOI: https://doi.org/10.1007/s00396-018-4292-0

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