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000256304 037__ $$aFZJ-2015-06268
000256304 041__ $$aEnglish
000256304 1001_ $$0P:(DE-Juel1)131034$$aWiegand, Simone$$b0$$eCorresponding author$$ufzj
000256304 1112_ $$a2015 International Meeting for optical Manipulation in Complex Systems$$cCavite$$d2015-10-22 - 2015-10-24$$wPhilippines
000256304 245__ $$aThermophoresis of charged colloidal spheres and rods
000256304 260__ $$c2015
000256304 3367_ $$0PUB:(DE-HGF)6$$2PUB:(DE-HGF)$$aConference Presentation$$bconf$$mconf$$s1446801609_12654$$xInvited
000256304 3367_ $$033$$2EndNote$$aConference Paper
000256304 3367_ $$2DataCite$$aOther
000256304 3367_ $$2ORCID$$aLECTURE_SPEECH
000256304 3367_ $$2DRIVER$$aconferenceObject
000256304 3367_ $$2BibTeX$$aINPROCEEDINGS
000256304 502__ $$cUni. Cavite, Philippines
000256304 520__ $$aRecently Dhont and Briels [1] calculated the double-layer contribution to the single-particle thermal diffusion coefficient of charged, spherical colloids with arbitrary double-layer thickness. In this approach three forces are taken into account, which contribute to the total thermophoretic force on a charged colloidal sphere due its double layer: i) the force FW that results from the temperature dependence of the internal electrostatic energy W of the double layer, ii) the electric force Fel with which the temperature-induced non-spherically symmetric double-layer potential acts on the surface charges of the colloidal sphere and iii) the solvent-friction force Fsol on the surface of the colloidal sphere due to the solvent flow that is induced in the double layer because of its asymmetry. This concept has successfully been used to describe the Soret coefficient of Ludox particles as function of the Debye length [2] (cf. Fig. 1). The surface charge density of the Ludox particles is independently obtained from electrophoresis measurements, the size of the colloidal particles is obtained from electron microscopy, and the Debye length is calculated from the ion concentration. Therefore the only adjustable parameter in the comparison with theory is the intercept at zero Debye length, which measures the contribution to the Soret coefficient of the solvation layer and possibly the colloid core material.Later the concept was extended for charged colloidal rods [3]. As model system we used the charged, rod-like fd-virus. The Soret coefficient of the fd-viruses increases monotonically with increasing Debye length, while there is a relatively weak dependence on the rod-concentration when the ionic strength is kept constant. Additionally to the intercept at zero Debye length we used the surface charge density as an adjustable parameter. Experimentally we found a surface charge density of 0.050±0.003 e/nm2, which compares well the surface charge density, of 0.066±0.004 e/nm2, which has been determined by electrophoresis measurements taking into account the ion condensation.All experiments so far have been performed with the so-called infrared thermal diffusion forced Rayleigh scattering technique [4]. This method uses the refractive index contrast between the different components and is therefore typically limited to binary mixtures. In order to study also biological colloids in buffer solutions we are presently developing a microscopic cell with heated wires. First results for some fluorescently labelled polystyrene lattices in the microwire cell are presented in comparison with thermal diffusion forced Rayleigh scattering measurements.REFERENCES[1] J.K.G. Dhont and W.J. Briels, Eur. Phys. J. E 25, 61(2008).[2] H. Ning, J.K.G. Dhont, and S. Wiegand, Langmuir, 24, 2426(2008).[3] Z. Wang et al., Soft Matter, 9, 8697(2013).[4] S. Wiegand, H. Ning, and H. Kriegs, J. Phys. Chem. B, 111, 14169(2007). Keywords: Thermophoresis, colloids, aqueous mixtures, holographic grating technique, microfluidic
000256304 536__ $$0G:(DE-HGF)POF3-551$$a551 - Functional Macromolecules and Complexes (POF3-551)$$cPOF3-551$$fPOF III$$x0
000256304 7001_ $$0P:(DE-Juel1)144600$$aAfanasenkau, Dzmitry$$b1$$ufzj
000256304 7001_ $$0P:(DE-Juel1)144087$$aWang, Zilin$$b2$$ufzj
000256304 7001_ $$0P:(DE-Juel1)130577$$aBuitenhuis, Johan$$b3$$ufzj
000256304 7001_ $$0P:(DE-Juel1)130616$$aDhont, Jan K.G.$$b4$$ufzj
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000256304 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)144600$$aForschungszentrum Jülich GmbH$$b1$$kFZJ
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000256304 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)130577$$aForschungszentrum Jülich GmbH$$b3$$kFZJ
000256304 9101_ $$0I:(DE-588b)5008462-8$$6P:(DE-Juel1)130616$$aForschungszentrum Jülich GmbH$$b4$$kFZJ
000256304 9131_ $$0G:(DE-HGF)POF3-551$$1G:(DE-HGF)POF3-550$$2G:(DE-HGF)POF3-500$$3G:(DE-HGF)POF3$$4G:(DE-HGF)POF$$aDE-HGF$$bKey Technologies$$lBioSoft – Fundamentals for future Technologies in the fields of Soft Matter and Life Sciences$$vFunctional Macromolecules and Complexes$$x0
000256304 9141_ $$y2015
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