<h4 align="center">WIGNER SZFI SZEMINÁRIUM</h4>
<h2 align="center">RALF STANNARIUS</h2>
<p align="center">(Dept. of Nonlinear Phenomena, Otto von Guericke Uni Magdeburg, vendéglátó: Börzsönyi Tamás)</p>
<h2 align="center">"Freely suspended liquid crystal films: liquids in 2D"</h2>
<p align="center">Időpont: 2015. december 10. (csütörtök) 10:00 (1 óra)<br>
Hely: MTA Wigner FK SZFI, I. épület 1. emeleti Tanácsterem</p>
<h3>Összefoglaló:</h3>
<p><span>Smectic free-standing films and bubbles are interesting not only from an aesthetic point of view. Director patterns and dynamics in smectic films have been used to study coupling of orientation and shear flow in quasi two-dimensional (2D) liquids, and they may serve as convenient model systems for in-plane isotropic and anisotropic membranes. In particular, the mobility of inclusions in a 2D liquid is qualitatively different from the 3D problem. We demonstrate with a 2D rheometer setup the qualitative and quantitative analysis of particle mobility in those membranes and test theoretical models. Experiments in microgravity are currently performed on the ISS within the project OASIS.</span></p>
<p><span>Freely floating smectic bubbles show additional exciting features, in particular a unique shape dynamics outside equilibrium, oscillations, or bursting. In these closed films, 2D fluid flow couples to the 3D flow of the surrounding gas. Substantial advantages over soap films [1] in experiments are the well-defined and uniform thicknesses of smectic films, and the absence of drainage.</span></p>
<p><span>Experiments with freely floating films were performed in microgravity during parabolic flights, providing 22 s of weightlessness. The dynamics of such freely floating, meniscus-free smectic films are qualitatively different from soap films or suspended smectic films, somewhere intermediate between vesicle dynamics and classical soap film dynamics. Surface tension competes with the </span>dislocation dynamics in the smectic layer structure [2].</p>
<p><span>In bursting thin smectic films, the retracting film edge exhibits a complex filamentation [3], which can be interpreted as the result of a flapping instability.</span></p>
<p><br />[1] U. Kornek et al.. New J. Phys., 12 073031, (2010).<br />[2] K. May, K. Harth, T. Trittel, and R. Stannarius. Europhys. Lett., 100 16003, (2012).<br />[3] T. Trittel, Th. John, K. Tsuji, and R. Stannarius.Phys. Fluids, 25 052106, (2013).</p>
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<p><b>Részletes információ:</b>
<a href="http://www.szfki.hu/seminar">http://www.szfki.hu/seminar</a></p>
<h4 align="center">Minden érdeklődőt szívesen látunk!</h4><p align="center">Asbóth János<br>szfi-seminar@wigner.mta.hu</p><p> </p>