Add to ORKGWe present an automated procedure for the design of optimal actuation for flagellar magnetic microswimmers based on numerical optimization. Using this method, a new magnetic actuation method is provided which allows these devices to swim significantly faster compared to the usual sinusoidal actuation. This leads to a novel swimming strategy which makes the swimmer perform a 3D figure-8 trajectory. This shows that a faster propulsion is obtained when the swimmer is allowed to go out-of-plane. This approach is experimentally validated on a scaled-up flexible swimmer
We propose a methodology for swimming at low-Reynolds-number flows based on ciliary motion of a micr...
The realization of artificial microscopic swimmers able to propel in viscous fluids is an emergent r...
International audienceWe discuss a reduced model to compute the motion of slender swimmerswhich prop...
International audienceWe present an automated procedure for the design of optimal actuation for flag...
International audienceIn this article, we present a simplified model of a flagellar magnetic micro-s...
International audience<table border="0" cellpadding="0" cellspacing="0" width="568" style="border-co...
We present an experimental realisation of two new artificial microswimmers that swim at low Reynolds...
Copyright © 2008 The American Physical SocietyWe propose a model for a novel artificial low Reynolds...
The unique swimming strategies of natural microorganisms have inspired recent development of magneti...
In this thesis, we investigate magnetically actuated rigid microswimmers based on analytical and num...
We study magnetic artificial flagella whose swimming speed and direction can be controlled using lig...
International audienceSynthetic microswimmers mimicking biological movements at the microscale have ...
A novel mechanism for actuating a miniature swimming robot is described, modeled, and experimentall...
We study magnetic artificial flagella whose swimming speed and direction can be controlled using lig...
Artificial bacteria flagella (ABFs) are magnetic helical microswimmers that can be remotely controll...
We propose a methodology for swimming at low-Reynolds-number flows based on ciliary motion of a micr...
The realization of artificial microscopic swimmers able to propel in viscous fluids is an emergent r...
International audienceWe discuss a reduced model to compute the motion of slender swimmerswhich prop...
International audienceWe present an automated procedure for the design of optimal actuation for flag...
International audienceIn this article, we present a simplified model of a flagellar magnetic micro-s...
International audience<table border="0" cellpadding="0" cellspacing="0" width="568" style="border-co...
We present an experimental realisation of two new artificial microswimmers that swim at low Reynolds...
Copyright © 2008 The American Physical SocietyWe propose a model for a novel artificial low Reynolds...
The unique swimming strategies of natural microorganisms have inspired recent development of magneti...
In this thesis, we investigate magnetically actuated rigid microswimmers based on analytical and num...
We study magnetic artificial flagella whose swimming speed and direction can be controlled using lig...
International audienceSynthetic microswimmers mimicking biological movements at the microscale have ...
A novel mechanism for actuating a miniature swimming robot is described, modeled, and experimentall...
We study magnetic artificial flagella whose swimming speed and direction can be controlled using lig...
Artificial bacteria flagella (ABFs) are magnetic helical microswimmers that can be remotely controll...
We propose a methodology for swimming at low-Reynolds-number flows based on ciliary motion of a micr...
The realization of artificial microscopic swimmers able to propel in viscous fluids is an emergent r...
International audienceWe discuss a reduced model to compute the motion of slender swimmerswhich prop...