Difference between revisions of "Modeling: Pattern formation using Reaction-Diffusion models"
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'''Biological or Medical aspects''': It will be investigated to which extend this model can explain the patterns observed on animals such as leopards or zebras. | '''Biological or Medical aspects''': It will be investigated to which extend this model can explain the patterns observed on animals such as leopards or zebras. | ||
| − | '''Supervisor''': [[User:Micha Hersch]] | + | '''Supervisor''': [[User:Micha|Micha Hersch]] |
'''References''': | '''References''': | ||
Revision as of 13:16, 16 February 2009
Background: One of the most amazing properties of biological systems is their ability to form complex and organized structures. Those structures range from simple patterns (like the stripes of a zebra) to highly complex constructs (like a cell). How such structures or patterns can emerge by themselves remains a largely unsolved problem. In this project, we investigate how a simple pattern can emerge in a decentralized manner, without any plan.
Goal: The goal of the project is to understand and analyze (with computer simulations) one of the simplest and most influential pattern formation mechanism using Reaction-Diffusion models.
Mathematical tools: This project uses partial differential equations. A short introduction to partial differential equations will be provided. A mathematical software for performing simulations (matlab) will also be used.
Biological or Medical aspects: It will be investigated to which extend this model can explain the patterns observed on animals such as leopards or zebras.
Supervisor: Micha Hersch
References:
The pioneering paper from Alan Turing <biblio>
- turing53chemical pmid=2185858 pdf file
</biblio>
(Project in Course: "Solving Biological Problems that require Math")
