Hauptseminar Active Matter SS 2017/Synthetic Microswimmers

From ICPWiki
< Hauptseminar Active Matter SS 2017
Revision as of 18:08, 27 January 2017 by Mkuron (talk | contribs) (Created page with "{{Seminartopic |topic=Synthetic Microswimmers |speaker=tba |date=2017-04-25 |time=14:00 |tutor=[http://www.pi2.uni-stuttgart.de/cms/index.php?article_id=79&id=cb2 Clemens Bech...")
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search
"{{{number}}}" is not a number.
Date
2017-04-25
Time
14:00
Topic
Synthetic Microswimmers
Speaker
tba
Tutor
Clemens Bechinger

Contents

The first attempts at creating such particles by the group of Prof. J. Bibette are considered to provide a background as 'mechanical' swimmers [1-2]. Synthetic microswimmers have recently stimulated considerable research interest from experimental and theoretical viewpoints. Self-phoretic effects have shown to be an effective and promising strategy to design such artificial microswimmers, where the microswimmers are driven by gradient fields locally produced by swimmers themselves in the surrounding solvent. Self-phoretic swimmers are typically composed of two parts: a functional part which modifies the surrounding solvent properties creating local gradient fields, and a non-functional part which is exposed then to the local field gradients [3-4]. Most existing experimental investigations of the self-phoretic microswimmers consider Janus particles, which can be quite easily synthesized using partial metal coating on colloidal spheres. In diffusio-phoretic microswimmers, the metal coated part catalyzes a chemical reaction to induce a concentration gradient [5-6]. When such particles are suspended in a binary mixture with a lower critical point and illuminated with light, the fluid locally demixes, which causes a self-diffusiophoretic motion [7]. In thermophoretic microswimmers, the metal coated part is able to effectively absorb heat from e.g. an external laser, which creates a local temperature gradient [8].

Literature

  1. D. Dreyfus et al., Nature 437, 862 (2005)
  2. P. Tierno et al., J. Phys. Chem. B 112, 16525 (2008)
  3. J. Anderson, Annu. Rev. Fluid Mech. 21, 61 (1989)
  4. J.F. Brady, J. Fluid Mech. 667, 216 (2011)
  5. J. R. Howse, R. A. L. Jones, A. J. Ryan, T. Gough, R. Vafabakhsh, and R. Golestanian, Phys. Rev. Lett. 99, 048102 (2007).
  6. J. Palacci, C. Cottin-Bizonne, C. Ybert, and L. Bocquet, Phys. Rev. Lett. 105, 088304 (2010).
  7. I. Buttinoni, G. Volpe, F. Kümmel, G. Volpe, and C. Bechinger, J. Phys. Condens. Matter 24, 284129 (2012).
  8. H.-R. Jiang, N. Yoshinaga, and M. Sano, Phys. Rev. Lett.105, 268302 (2010).
Retrieved from "https://www2.icp.uni-stuttgart.de/~icp/mediawiki/index.php?title=Hauptseminar_Active_Matter_SS_2017/Synthetic_Microswimmers&oldid=21627"