Martin Kraus scite author profile

The shape dynamics of fluid vesicles is governed by the coupling of the flow within the two-dimensional membrane to the hydrodynamics of the surrounding bulk fluid. We present a numerical scheme which is capable of solving this flow problem for arbitrarily shaped vesicles using the Oseen tensor formalism. For the particular problem of simple shear flow, stationary shapes are found for a large range of parameters. The dependence of the orientation of the vesicle and the membrane velocity on shear rate and vesicle volume can be understood from a simplified model.Comment: 10 pages, LaTeX2e, psfig, 5 eps figures included, to appear in Phys. Rev. Lett., 199

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Mapping vesicle shapes into the phase diagram: A comparison of experiment and theory

Döbereiner

et al. 1997

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Phase-contrast microscopy is used to monitor the shapes of micron-scale fluid-phase phospholipid-bilayer vesicles in aqueous solution. At fixed temperature, each vesicle undergoes thermal shape fluctuations. We are able experimentally to characterize the thermal shape ensemble by digitizing the vesicle outline in real time and storing the time-sequence of images. Analysis of this ensemble using the area-difference-elasticity (ADE) model of vesicle shapes allows us to associate (map) each time-sequence to a point in the zerotemperature (shape) phase diagram. Changing the laboratory temperature modifies the control parameters (area, volume, etc.) of each vesicle, so it sweeps out a trajectory across the theoretical phase diagram. It is a nontrivial test of the ADE model to check that these trajectories remain confined to regions of the phase diagram where the corresponding shapes are locally stable. In particular, we study the thermal trajectories of three prolate vesicles which, upon heating, experienced a mechanical instability leading to budding. We verify that the position of the observed instability and the geometry of the budded shape are in reasonable accord with the theoretical predictions. The inability of previous experiments to detect the "hidden" control parameters (relaxed area difference and spontaneous curvature) make this the first direct quantitative confrontation between vesicle-shape theory and experiment. submitted to PRE Typeset using REVT E X 1

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CO2 reforming of methane by the combination of dielectric-barrier discharges and catalysis

Kraus

Eliasson

Kogelschatz

et al. 2001

Phys. Chem. Chem. Phys.

198

147

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Investigation of mechanistic aspects of the catalytic CO2 reforming of methane in a dielectric-barrier discharge using optical emission spectroscopy and kinetic modeling

Kraus

Egli²,

Haffner

et al. 2002

Phys. Chem. Chem. Phys.

115

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Martin Kraus

Fluid Vesicles in Shear Flow

Mapping vesicle shapes into the phase diagram: A comparison of experiment and theory

CO2 reforming of methane by the combination of dielectric-barrier discharges and catalysis

Investigation of mechanistic aspects of the catalytic CO2 reforming of methane in a dielectric-barrier discharge using optical emission spectroscopy and kinetic modeling

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