Difference between revisions of "Hauptseminar Porous Media SS 2021/Bacteria in porous media"

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{{Seminartopic
 
{{Seminartopic
 +
|number=9
 
|topic=Modelling bacteria in porous media
 
|topic=Modelling bacteria in porous media
|speaker= TBD
+
|speaker= Kevin Vietz
|date=4.9.2021
+
|date=2021-07-02
|time=TBA
+
|time=14:30
 
|tutor=[[Christoph Lohrmann]]
 
|tutor=[[Christoph Lohrmann]]
 
|handout=
 
|handout=
Line 9: Line 10:
  
 
== Contents ==
 
== Contents ==
 +
Motile bacteria are a prime example of active matter.
 +
They are, in contrast to passive particles like molecules or colloids, far from equilibrium in any system because of their self-propulsion.
 +
This leads to interesting and sometimes counterintuitive transport properties, especially if the swimmers are placed in porous confinement.
  
Application: MICP
+
This talk covers the fundamentals of the statistics and hydrodynamics of confined motile active matter at the micrometer scale.
 +
For different regimes of pore sizes, the relevant physics of the interplay between motility, confinement and external flow are discussed:
 +
For small pores, confinement determines the motility pattern, whereas for large surfaces hydrodynamics is the dominant factor.
 +
For intermediate pore sizes, all effects act together and create interesting phenomena.
 +
We will also highlight industrial applications of bacteria in porous media.
  
 
== Literature ==
 
== Literature ==
  
TBA
+
<bibentry pdflink="yes">
 +
bechinger16a
 +
bhattacharjee19a
 +
rusconi14a
 +
lee20a
 +
mujah17a
 +
</bibentry>

Latest revision as of 09:50, 4 March 2021

Date
2021-07-02
Time
14:30
Topic
Modelling bacteria in porous media
Speaker
Kevin Vietz
Tutor
Christoph Lohrmann

Contents

Motile bacteria are a prime example of active matter. They are, in contrast to passive particles like molecules or colloids, far from equilibrium in any system because of their self-propulsion. This leads to interesting and sometimes counterintuitive transport properties, especially if the swimmers are placed in porous confinement.

This talk covers the fundamentals of the statistics and hydrodynamics of confined motile active matter at the micrometer scale. For different regimes of pore sizes, the relevant physics of the interplay between motility, confinement and external flow are discussed: For small pores, confinement determines the motility pattern, whereas for large surfaces hydrodynamics is the dominant factor. For intermediate pore sizes, all effects act together and create interesting phenomena. We will also highlight industrial applications of bacteria in porous media.

Literature