Abstract
Freely suspended smectic films with in-plane temperature inhomogeneities can exhibit remarkable thermocapillary (Marangoni) effects. The temperature dependence of the surface tension promotes flow in the film plane, convection roll patterns, and climbing of smectic layers against gravitational forces. We discuss several experimental geometries where macroscopic material transport is driven by temperature gradients, including experiments under normal gravity and observations in microgravitation during suborbital rocket flights and on the International Space Station. In all these experiments, the temperature dependence of the surface tension drives unidirectional material flow. The divergence of this flow near the hot and cold film edges, and at the boundaries of film islands in the film, is associated with the creation, motion and removal of dislocations. These dissipative processes limit the flow velocity.
Highlights
Liquid crystals (LCs) play a dominant role in display technology today, and their unique ferroelectric, pyroelectric and flexoelectric properties make them attractive for many other applications such as sensors and actuators
We describe qualitatively the effects of thermal gradients in the geometry of spherical smectic bubbles supported by a heated needle in microgravity, including the transport of inclusions in the films
The principal mechanism that is responsible for flow in freely suspended smectic films with in-plane temperature gradients has been discussed in a previous publication [32]
Summary
Netherlands 3 Soft Materials Research Center, Physics Department, University of Colorado, Boulder, CO 80309, United States of America.
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