Add to ORKGSmall organisms (e.g., bacteria) and artificial microswimmers move due to a combination of active swimming and passive Brownian motion. Considering a simplified linear three-sphere swimmer, we study how the swimmer size regulates the interplay between self-driven and diffusive behavior at low Reynolds number. Starting from the Kirkwood-Smoluchowski equation and its corresponding Langevin equation, we derive formulas for the orientation correlation time, the mean velocity and the mean-square displacement in three space dimensions. The validity of the analytical results is illustrated through numerical simulations. Tuning the swimmer parameters to values that are typical of bacteria, we find three characteristic regimes: (i) Brownian motion a...
International audienceIn this Letter, we study the collective behavior of a large number of self-pro...
Active matter systems are continuously consuming energy from the environment to achieve different pu...
In this Letter, we study the collective behavior of a large number of self-propelled microswimmers i...
Small organisms (e.g., bacteria) and artificial microswimmers move due to a combination of active sw...
Small organisms (e.g., bacteria) and artificial microswimmers move due to a combination of active sw...
The present work contains original research on the field of biophysics, specifically the study of sw...
Active matter exhibits various forms of nonequilibrium states in the absence of external forcing, in...
Cell motility in viscous fluids is ubiquitous and affects many biological processes, including repro...
Swimming cells and microorganisms must often move through complex fluids that contain an immersed mi...
In this Letter, we study the collective behavior of a large number of self-propelled microswimmers i...
International audienceSwimming at a micrometer scale demands particular strategies. Indeed when iner...
International audienceIn this Letter, we study the collective behavior of a large number of self-pro...
Contrary to microbial taxis, where a tactic response to external stimuli is controlled by complex ch...
At the macroscopic level and in the absence of interacting chemical gradients, the motility of a pop...
As technological advances allow us to fabricate smaller autonomous self-propelled devices, it is cle...
International audienceIn this Letter, we study the collective behavior of a large number of self-pro...
Active matter systems are continuously consuming energy from the environment to achieve different pu...
In this Letter, we study the collective behavior of a large number of self-propelled microswimmers i...
Small organisms (e.g., bacteria) and artificial microswimmers move due to a combination of active sw...
Small organisms (e.g., bacteria) and artificial microswimmers move due to a combination of active sw...
The present work contains original research on the field of biophysics, specifically the study of sw...
Active matter exhibits various forms of nonequilibrium states in the absence of external forcing, in...
Cell motility in viscous fluids is ubiquitous and affects many biological processes, including repro...
Swimming cells and microorganisms must often move through complex fluids that contain an immersed mi...
In this Letter, we study the collective behavior of a large number of self-propelled microswimmers i...
International audienceSwimming at a micrometer scale demands particular strategies. Indeed when iner...
International audienceIn this Letter, we study the collective behavior of a large number of self-pro...
Contrary to microbial taxis, where a tactic response to external stimuli is controlled by complex ch...
At the macroscopic level and in the absence of interacting chemical gradients, the motility of a pop...
As technological advances allow us to fabricate smaller autonomous self-propelled devices, it is cle...
International audienceIn this Letter, we study the collective behavior of a large number of self-pro...
Active matter systems are continuously consuming energy from the environment to achieve different pu...
In this Letter, we study the collective behavior of a large number of self-propelled microswimmers i...