Difference between revisions of "Hauptseminar Active Matter SS 2015/Life at Low Reynolds Numbers: Nature`s Strategy for Motion at Small Length Scales (T)"
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{{Seminartopic | {{Seminartopic | ||
|topic=Life at Low Reynolds Numbers: Nature`s Strategy for Motion at Small Length Scales (T) | |topic=Life at Low Reynolds Numbers: Nature`s Strategy for Motion at Small Length Scales (T) | ||
− | |speaker= | + | |speaker=Karoline Weinspach |
− | |date= | + | |date=22.04.2015 |
− | |tutor= | + | |tutor=Georg Rempfer |
}} | }} | ||
== Contents == | == Contents == | ||
− | In this topic the concept of self-propulsion in biological systems is discussed. In particular the consequences of living in an incompressible/viscous medium on the micron length scale. The concept of irreversibility will be introduced via Purcell's famous scallop theorem. The various mechanisms by which micro-organisms achieve motion are considered in connection to irreversibility. | + | In this topic the concept of self-propulsion in biological systems is discussed. In particular the consequences of living in an incompressible/viscous medium on the micron length scale. The concept of irreversibility will be introduced via Purcell's famous scallop theorem. The various mechanisms by which micro-organisms achieve motion are considered in connection to irreversibility. In relation to their strategies to achieve self-propulsion, the far-field hydrodynamic signature of these objects is discussed and the consequences these hydrodynamic modes have for their interaction with walls and other particles. |
== Literature == | == Literature == | ||
Line 17: | Line 17: | ||
* A. Najafi and R. Golestanian, J. Phys.: Condens. Matter 19, S1203 (2005) | * A. Najafi and R. Golestanian, J. Phys.: Condens. Matter 19, S1203 (2005) | ||
* O.S. Pak and Eric Lauga, arXiv:1410.4321v1 (2014) | * O.S. Pak and Eric Lauga, arXiv:1410.4321v1 (2014) | ||
+ | * D.O. Pushkin, H. Shum, and J.M. Yeomans, J. Fluid Mech. 726, 5 (2013) |
Latest revision as of 14:10, 17 December 2014
More information will become available soon.
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- Date
- 22.04.2015
- Topic
- Life at Low Reynolds Numbers: Nature`s Strategy for Motion at Small Length Scales (T)
- Speaker
- Karoline Weinspach
- Tutor
- Georg Rempfer
Contents
In this topic the concept of self-propulsion in biological systems is discussed. In particular the consequences of living in an incompressible/viscous medium on the micron length scale. The concept of irreversibility will be introduced via Purcell's famous scallop theorem. The various mechanisms by which micro-organisms achieve motion are considered in connection to irreversibility. In relation to their strategies to achieve self-propulsion, the far-field hydrodynamic signature of these objects is discussed and the consequences these hydrodynamic modes have for their interaction with walls and other particles.
Literature
- E.M. Purcell, Am. J. Phys. 45, 3 (1977)
- A. Najafi and R. Golestanian, J. Phys.: Condens. Matter 19, S1203 (2005)
- O.S. Pak and Eric Lauga, arXiv:1410.4321v1 (2014)
- D.O. Pushkin, H. Shum, and J.M. Yeomans, J. Fluid Mech. 726, 5 (2013)