Your search keyword '"Ripoll, Marisol"' showing total 4 results

1. Chemically driven fluid transport in long microchannels.

Author

Mingren Shen, Fangfu Ye, Rui Liu, Ke Chen, Mingcheng Yang, and Ripoll, Marisol

Subjects

MICROCHANNEL flow, BOUNDARY wall method (Quantum mechanics), NANOFLUIDICS, SIMULATION methods & models, DIFFUSION

Abstract

Chemical gradients maintained along surfaces can drive fluid flows by diffusio-osmosis, which become significant at micro- and nano-scales. Here, by means of mesoscopic simulations, we show that a concentration drop across microchannels with periodically inhomogeneous boundary walls can laterally transport fluids over arbitrarily long distances along the microchannel. The driving field is the secondary local chemical gradient parallel to the channel induced by the periodic inhomogeneity of the channel wall. The flow velocity depends on the concentration drop across the channel and the structure and composition of the channel walls, but it is independent of the overall channel length. Our work thus presents new insight into the fluid transport in long microchannels commonly found in nature and is useful for designing novel micro- or nano-fluidic pumps. [ABSTRACT FROM AUTHOR]

Published

2016

2. Collective thermodiffusion of colloidal suspensions.

Author

Lüsebrink, Daniel and Ripoll, Marisol

Subjects

*DIFFUSION, *SUSPENSIONS (Chemistry), *COLLOIDS, *THERMAL analysis, *THERMODYNAMICS, *SIMULATION methods & models

Abstract

The thermophoretic behavior of concentrated colloidal suspensions can be understood as the sum of single particle and collective effects. Here, we present a simulation model to investigate the particularities of the collective thermodiffusive effects in concentrated uncharged solutions, where the influence of different colloid-colloid interactions is analyzed. The concentration dependence found in our simulations qualitatively agrees with experimental results. Colloids with repulsive interactions are found to accumulate more effectively than the solvent in the warm areas, such that the corresponding Soret coefficients are negative and decrease with increasing concentration. The accumulation of colloids in the cold regions is facilitated by attraction, such that colloids with attractive interactions have larger values of the Soret coefficient. A thermodynamic argument that explains our results from equilibrium quantities is discussed as well. [ABSTRACT FROM AUTHOR]

Published

2012

3. Temperature inhomogeneities simulated with multiparticle-collision dynamics.

Author

Lüsebrink, Daniel and Ripoll, Marisol

Subjects

*TEMPERATURE lapse rate, *ACCURACY, *SIMULATION methods & models, *POWER (Mechanics), *DIFFUSION

Abstract

The mesoscopic simulation technique known as multiparticle collision dynamics is presented as a very appropriate method to simulate complex systems in the presence of temperature inhomogeneities. Three different methods to impose the temperature gradient are compared and characterized in the parameter landscape. Two methods include the interaction of the system with confining walls. The third method considers open boundary conditions by imposing energy fluxes. The transport of energy characterizing the thermal diffusivity is also investigated. The dependence of this transport coefficient on the method parameters and the accuracy of existing analytical theories is discussed. [ABSTRACT FROM AUTHOR]

Published

2012

4. Simulations of thermophoretic nanoswimmers.

Author

Yang, Mingcheng and Ripoll, Marisol

Subjects

*THERMOPHORESIS, *SYMMETRY (Physics), *PROPULSION systems, *TEMPERATURE inversions, *NANOTECHNOLOGY, *SIMULATION methods & models, *THERMAL properties, *MATHEMATICAL physics

Abstract

We consider a nanodimer in solution with asymmetric thermal properties that shows self-propelled motion. One monomer of the nanodimer can be heated to a fixed temperature producing a radially symmetric temperature gradient. The thermophoretic properties of the second monomer produce then a propulsion against or toward the heated particle, such that the nanodimer becomes a puller or pusher nanoswimmer. We combine our simulation measurements with a theoretical analysis that satisfactorily characterizes the self-propelled velocity with the temperature gradient, and the thermophoretic properties of the bead. [ABSTRACT FROM AUTHOR]

Published

2011