Team:SDU-Denmark/project-m

From 2010.igem.org

(Difference between revisions)
(Flagella dynamics)
(Description of model)
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=== Description of model ===
=== Description of model ===
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A flagellum creates propulsion by spinning around in a helical shape. Since the flagella/flagellabundles, take on a helical shape, the most accurate thing to do would be to model them as such, but doing this would become quite advanced for even one flagellum, not to mention an entire system. Since we are limited in both time and computerpower, we will have to simplify the system a bit.
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A flagellum creates propulsion by spinning around in a helical shape. Since the flagellum/flagellabundles take on a helical shape, the most accurate thing to do would be to model them as such, but doing this would become quite advanced for even one flagellum, not to mention an entire system. Since we are limited in both time and computer power, we will have to simplify the system a bit.
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One thing we can do is to consider all the flagella of a bacterium to form one bundle, even though doing so for a bacterium stuck to a wall is questionable.
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One thing we can do is to consider all the flagella of a bacterium to form one bundle, even though doing so for a bacterium stuck to a wall is questionable. <br>
The overall result of this spinning bundle is that the flow moves in an almost straight line. This could be modelled as a pointforce on the tip of the flagellabundle pointing in the same direction as the bundle.
The overall result of this spinning bundle is that the flow moves in an almost straight line. This could be modelled as a pointforce on the tip of the flagellabundle pointing in the same direction as the bundle.
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The size of this force can be approximated by calculating the drag on a swimming bacterium. If the bacterium is considered almost spherical the drag force can be calculated by using the formula for Stokes flow past a sphere:
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The size of this force can be approximated by calculating the drag on a swimming bacterium. If the bacterium is considered almost spherical, the drag force can be calculated by using the formula for Stokes flow past a sphere:
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[[Image:Team-SDU-Denmark-2010-Dragforce.gif|center]]
[[Image:Team-SDU-Denmark-2010-Dragforce.gif|center]]
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[[Image:Team-SDU-Denmark-2010-ColiForce.gif|center]]
[[Image:Team-SDU-Denmark-2010-ColiForce.gif|center]]
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The system we are trying to model consists of a lot of bacteria stuck to a wall, but the part we are interested in is the flagellae and the forces they create. We therefore ignore the bodies of the bacteria, and instead consider the flagella as being stuck directly to the wall, with one end glued to the wall and the other pointing out into the fluid.  
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The system we are trying to model consists of a lot of bacteria stuck to a wall, but the part we are interested in is the flagella and the forces they create. We therefore ignore the bodies of the bacteria, and instead consider the flagella as being stuck directly to the wall, with one end glued to the wall and the other pointing out into the fluid.  
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Next step is to figure out what kind of flowfield, such a pointforce creates. The flowfield created by a pointforce in a fluid with no walls or other obstructions near it can be calculated using the corresponding Green's function known as the stokeslet:
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Next step is to figure out what kind of flowfield such a pointforce creates. The flowfield created by a pointforce in a fluid with no walls or other obstructions near it can be calculated using the corresponding Green's function known as the stokeslet:
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[[Image:Team-SDU-Denmark-Oseen 0.gif|center]]
[[Image:Team-SDU-Denmark-Oseen 0.gif|center]]
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The two formulas above are based on [[https://2010.igem.org/Team:SDU-Denmark/project-m#Litterature 8]].
The two formulas above are based on [[https://2010.igem.org/Team:SDU-Denmark/project-m#Litterature 8]].
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In our case the system we are trying to describe is a microtube. This means that the width of the tube is so small, that the forces created by the flagella are not only close to the wall to which the bacteria are stuck, but also close to the opposite wall. This presents an interesting problem. Since the Oseen-Blake tensor works by creating a mirrorpoint of the real force on the opposite side of the wall, we will need a mirrorpoint behind the other wall if we are to uphold the no-slip condition. But the mirror forces also affect the flow near the other wall. In order to cancel this effect one could create another mirrorforce, corresponding to each of the mirror forces, but of course these would obstruct each other to, requirering yet more mirror forces. In the end we decided to see how precise the system would be for one mirrorpoint behind each wall. This corresponds to taking the equation above and adding the three last terms once more, but with the mirrorvector corresponding to the other wall.<br>
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In our case the system we are trying to describe is a microtube. This means that the tube is so narrow that the forces created by the flagella are not only close to the wall to which the bacteria are stuck, but also close to the opposite wall. This presents an interesting problem. Since the Oseen-Blake tensor works by creating a mirrorpoint of the real force on the opposite side of the wall, we will need a mirrorpoint behind the other wall if we are to uphold the no-slip condition. But the mirror forces also affect the flow near the other wall. In order to cancel this effect one could create another mirrorforce, corresponding to each of the mirror forces, but of course these would obstruct each other to, requirering yet more mirror forces. In the end we decided to see how precise the system would be for one mirrorpoint behind each wall. This corresponds to taking the equation above and adding the three last terms once more, but with the mirrorvector corresponding to the other wall.<br>
The flowfield corresponding to this is shown below.
The flowfield corresponding to this is shown below.
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[[Image:Team-SDU-Denamrk-Pointforces_notxt.jpg|thumb|center|580px|'''Figure 3''' All 3 images show the flowfield created by a pointforce at (0.000007,0.000007) with an angle of 45 degrees with the x-axis. In the first image there are no walls. In the 2nd a wall is placed at y=0. In the 3rd one wall is placed at y=0 and one at y=0.000015]]  
[[Image:Team-SDU-Denamrk-Pointforces_notxt.jpg|thumb|center|580px|'''Figure 3''' All 3 images show the flowfield created by a pointforce at (0.000007,0.000007) with an angle of 45 degrees with the x-axis. In the first image there are no walls. In the 2nd a wall is placed at y=0. In the 3rd one wall is placed at y=0 and one at y=0.000015]]  
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As the above figures show, there is quite a difference depending on how many walls you take in to consideration. We decided to keep working with both the single-wall and the double-wall flowfields.
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As the above figures show, there is quite a difference depending on how many walls you take into consideration. We decided to keep working with both the single-wall and the double-wall flowfields.
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Revision as of 15:12, 27 October 2010