Add to ORKGWe describe a boundary-element method used to model the hydrodynamics of a bacterium propelled by a single helical flagellum. Using this model, we optimize the power efficiency of swimming with respect to cell body and flagellum geometrical parameters, and find that optima for swimming in unbounded fluid and near a no-slip plane boundary are nearly indistinguishable. We also consider the novel optimization objective of torque efficiency and find a very different optimal shape. Excluding effects such as Brownian motion and electrostatic interactions, it is demonstrated that hydrodynamic forces may trap the bacterium in a stable, circular orbit near the boundary, leading to the empirically observable surface accumulation of bacteria. Furtherm...
It is well known that flagellated bacteria swim in circles near surfaces. However, recent experiment...
The colonization of surfaces by bacteria is a widespread phenomenon with consequences on environment...
AbstractThis article evaluates the hydrodynamic interactions between two swimming bacteria precisely...
We describe a boundary-element method used to model the hydrodynamics of a bacterium propelled by a ...
Motility of flagellated bacteria has been a topic of increasing scientific interest over the past de...
A general Boundary Element Method is presented and benchmarked with existing Slender Body Theory res...
The near-surface motility of bacteria is important in the initial formation of biofilms and in many ...
We present a simple model for bacteria like Escherichia coil swimming near solid surfaces. It consis...
AbstractNear a solid boundary, Escherichia coli swims in clockwise circular motion. We provide a hyd...
The inuence of nearby solid surfaces on the motility of bacteria is of fundamental importance as the...
The presence of a nearby boundary is likely to be important in the life cycle and evolution of motil...
AbstractThe singly flagellated bacterium, Vibrio alginolyticus, moves forward and backward by altern...
A crucial structure in the motility of flagellated bacteria is the hook, which connects the flagellu...
The motility of bacteria plays an important role in their reproduction, energy balance, and predator...
International audienceFlagellated bacteria exploiting helical propulsion are known to swim along cir...
It is well known that flagellated bacteria swim in circles near surfaces. However, recent experiment...
The colonization of surfaces by bacteria is a widespread phenomenon with consequences on environment...
AbstractThis article evaluates the hydrodynamic interactions between two swimming bacteria precisely...
We describe a boundary-element method used to model the hydrodynamics of a bacterium propelled by a ...
Motility of flagellated bacteria has been a topic of increasing scientific interest over the past de...
A general Boundary Element Method is presented and benchmarked with existing Slender Body Theory res...
The near-surface motility of bacteria is important in the initial formation of biofilms and in many ...
We present a simple model for bacteria like Escherichia coil swimming near solid surfaces. It consis...
AbstractNear a solid boundary, Escherichia coli swims in clockwise circular motion. We provide a hyd...
The inuence of nearby solid surfaces on the motility of bacteria is of fundamental importance as the...
The presence of a nearby boundary is likely to be important in the life cycle and evolution of motil...
AbstractThe singly flagellated bacterium, Vibrio alginolyticus, moves forward and backward by altern...
A crucial structure in the motility of flagellated bacteria is the hook, which connects the flagellu...
The motility of bacteria plays an important role in their reproduction, energy balance, and predator...
International audienceFlagellated bacteria exploiting helical propulsion are known to swim along cir...
It is well known that flagellated bacteria swim in circles near surfaces. However, recent experiment...
The colonization of surfaces by bacteria is a widespread phenomenon with consequences on environment...
AbstractThis article evaluates the hydrodynamic interactions between two swimming bacteria precisely...