Add to ORKGConventionally, a microscopic particle that performs a reciprocal stroke cannot move through its environment. This is because at small scales, the response of simple Newtonian fluids is purely viscous and flows are time-reversible. We show that by contrast, fluid elasticity enables propulsion by reciprocal forcing that is otherwise impossible. We present experiments on rigid objects actuated reciprocally in viscous fluids, demonstrating for the first time a purely elastic propulsion set by the object’s shape and boundary conditions. We describe two different artificial “swimmers” that experimentally realize this principle
In this dissertation, the effects of elasticity on hydrodynamic interactions at small scales are inv...
The motility of microorganisms is influenced greatly by their hydrodynamic interactions with the flu...
Microscale propulsion is integral to numerous biomedical systems, including biofilm formation and hu...
Conventionally, a microscopic particle that performs a reciprocal stroke cannot move through its env...
In the absence of inertia, a reciprocal swimmer achieves no net motion in a viscous Newtonian fluid....
The effects of fluid elasticity on the swimming behavior of the nematode Caenorhabditis elegans are ...
A stiff one-armed swimmer in glycerine goes nowhere. However, if its arm is elastic, the swimmer can...
Many cells exploit the bending or rotation of flagellar filaments in order to self-propel in viscous...
Biological microorganisms swim with flagella and cilia that execute nonreciprocal motions for low Re...
Many small organisms self-propel in viscous fluids using travelling wave-like deformations of their ...
The current work studies the dynamics of a microswimmer in pressure-driven flow of a weakly viscoela...
Biological microorganisms swim with flagella and cilia that execute non-reciprocal motions for low R...
With the use of synthetic micro-swimmers in biomedical applications on the rise, a fundamental under...
Accepted for publication in Phys. Fluids.A simple way to generate propulsion at low Reynolds number ...
It has long been known that some microswimmers seem to swim counter-intuitively faster when the visc...
In this dissertation, the effects of elasticity on hydrodynamic interactions at small scales are inv...
The motility of microorganisms is influenced greatly by their hydrodynamic interactions with the flu...
Microscale propulsion is integral to numerous biomedical systems, including biofilm formation and hu...
Conventionally, a microscopic particle that performs a reciprocal stroke cannot move through its env...
In the absence of inertia, a reciprocal swimmer achieves no net motion in a viscous Newtonian fluid....
The effects of fluid elasticity on the swimming behavior of the nematode Caenorhabditis elegans are ...
A stiff one-armed swimmer in glycerine goes nowhere. However, if its arm is elastic, the swimmer can...
Many cells exploit the bending or rotation of flagellar filaments in order to self-propel in viscous...
Biological microorganisms swim with flagella and cilia that execute nonreciprocal motions for low Re...
Many small organisms self-propel in viscous fluids using travelling wave-like deformations of their ...
The current work studies the dynamics of a microswimmer in pressure-driven flow of a weakly viscoela...
Biological microorganisms swim with flagella and cilia that execute non-reciprocal motions for low R...
With the use of synthetic micro-swimmers in biomedical applications on the rise, a fundamental under...
Accepted for publication in Phys. Fluids.A simple way to generate propulsion at low Reynolds number ...
It has long been known that some microswimmers seem to swim counter-intuitively faster when the visc...
In this dissertation, the effects of elasticity on hydrodynamic interactions at small scales are inv...
The motility of microorganisms is influenced greatly by their hydrodynamic interactions with the flu...
Microscale propulsion is integral to numerous biomedical systems, including biofilm formation and hu...