Mechanism of Polymer Thermophoresis in Nonaqueous Solvents

Schimpf, Martin E.; Semenov, Semen N.

doi:10.1021/jp994334q

Cited by 58 publications

(57 citation statements)

References 10 publications

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“…5,[10][11][12][13][14][15] The main issues of interest were the derivation of scaling laws and to understand the sign change of the Soret coefficient for macromolecular and colloidal systems on the basis of existing theories for molecular fluids.…”

Section: 9mentioning

confidence: 99%

Thermal diffusion behavior of hard-sphere suspensions

Ning¹,

Buitenhuis²,

Dhont³

et al. 2006

The Journal of Chemical Physics

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We studied the thermal diffusion behavior of octadecyl coated silica particles (R h = 27 nm) in toluene between 15.0 • C and 50.0 • C in a volume fraction range of 1% to 30% by means of thermal diffusion forced Rayleigh scattering. The colloidal particles behave like hard spheres at high temperatures and as sticky spheres at low temperatures. With increasing temperature, the obtained Soret coefficient S T of the silica particles changed sign from negative to positive, which implies that the colloidal particles move to the warm side at low temperatures, whereas they move to the cold side at high temperatures. Additionally, we observed also a sign change of the Soret coefficient from positive to negative with increasing volume fraction. This is the first colloidal system for which a sign change with temperature and volume fraction has been observed. The concentration dependence of the thermal diffusion coefficient of the colloidal spheres is related to the colloid-colloid interactions, and will be compared with an existing theoretical description for interacting spherical particles. To characterize the particle-particle interaction parameters, we performed static and dynamic light scattering experiments. The temperature dependence of the thermal diffusion coefficient is predominantly determined by single colloidal particle properties, which are related to colloid-solvent molecule interactions.

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Section: 9mentioning

confidence: 99%

Thermal diffusion behavior of hard-sphere suspensions

Ning¹,

Buitenhuis²,

Dhont³

et al. 2006

The Journal of Chemical Physics

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“…Brock [12] improved on Epstein's solution by considering slip boundary conditions in the continuum derivations. Other attempts were made using the Boltzmann equation as the starting point of the analysis [13][14][15], but the validity of these approaches remains questionable [11,16,17].…”

Section: Introductionmentioning

confidence: 99%

Thermophoretic force and velocity of nanoparticles in the free molecule regime

Wang

2004

Phys. Rev. E

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We extend our previous gas-kinetic theory analysis of drag force in a uniform temperature field [Li and Wang, Phys. Rev. E. 68, 061206 (2003); 68, 061207 (2003)] to particle transport in fluids with nonuniform temperature. Formulations for drag and thermophoretic forces are proposed for nanoparticle transport in lowdensity gases. We specifically consider the influence of nonrigid body collision due to van der Waals or other forces between the particle and gas molecules and find that these forces play a notable role for particles a few nanometers in size. It is shown that the present formulations can be easily reduced to the classical result of Waldmann [Z. Naturforsch. A 14a, 589 (1959)] by assuming rigid body collision. From the force formulations we also obtain the equation governing the thermophoretic velocity. This velocity is found to be highly sensitive to the potential energy of interactions between gas molecules and particle, and as such Waldmann's thermophoretic velocity is not expected to be accurate for nanosized particles.

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“…When ionic systems or polymer -solvent pairs having strong interaction are considered, a more refined theory of thermodiffusion should be employed [30,31]. …”

Section: Discussionmentioning

confidence: 99%

Determination of calibration function in thermal field flow fractionation under thermal field programming

Pasti

Ventosa

Mingozzi³

et al. 2006

J of Separation Science

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A new procedure for determining the calibration function able to relate retention and operative parameters to molecular weight of the species in thermal field flow (ThFFF) under thermal field programming (TFP) conditions is presented. The procedure involves determining the average values of retention parameters under TFP and determining a numerical function related to the temperature variations that occur during TFP. The calibration parameters are obtained by a procedure fitting the retention and operative parameters that hold true at the beginning of the TFP. The procedure is closely related to the one previously developed to calibrate the retention time axis under TFP ThFFF and, together, they constitute a full calibration procedure. Experimental validation was performed with reference to polystyrene (PS)-decalin and PS-THF systems. The calibration functions here obtained were compared to those derived by the classical procedure at constant thermal field ThFFF to obtain the calibration function at variable cold wall temperatures. Excellent agreement was found in all cases proving "universality" of the ThFFF calibration concept, i.e. it is independent of the particular system on which it was determined and can thus be extended to ThFFF operating under TFP. The new procedure is simpler than the classical one since it requires less precision in setting the instrumentation and can be obtained with fewer experiments. The potential applications for the method are discussed.

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Mechanism of Polymer Thermophoresis in Nonaqueous Solvents

Cited by 58 publications

References 10 publications

Thermal diffusion behavior of hard-sphere suspensions

Thermal diffusion behavior of hard-sphere suspensions

Thermophoretic force and velocity of nanoparticles in the free molecule regime

Determination of calibration function in thermal field flow fractionation under thermal field programming

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