Add to ORKGWe study one-dimensional crawlers, namely, model mechanical systems that exploit cyclic shape changes and mechanical interactions with the environment to achieve self-propulsion. We focus on systems that can execute shape changes by propagating stretching or contraction waves along their bodies, and that interact with the substrate through viscous tangential forces. Two distinct rheologies are considered for the substrate: a linear Newtonian one, and a non-linear one of the Bingham type. Different behaviors result from the two rheologies and their implications in terms of motility performance are discussed. We believe that our results contribute to the general understanding of the key principles of limbless locomotion in natural and engin...
Non-pedal forms of locomotion show their advantages in inspection tech-niques or applications to the...
AbstractWith a simple and versatile microcantilever-based force measurement technique, we have probe...
Complex fluids are a broad class of materials that are usually homogeneous at macroscopic scales but...
We study one-dimensional crawlers, namely, model mechanical systems that exploit cyclic shape change...
We study model one-dimensional crawlers, namely, model mechanical systems that can achieve self-prop...
We study model self-propelled crawlers which derive their propulsive capabilities from the tangentia...
We study model locomotors on a substrate, which derive their propulsive capabilities from the tangen...
In this paper we study crawling locomotion based on directional frictional interactions, namely, fri...
We formulate and solve the locomotion problem for a bio-inspired crawler consisting of two active el...
We present experimental and numerical results for a model crawler which is able to extract net posit...
Inspired by the robust locomotion of limbless animals in a range of environments, the development of...
Nonlinear rheological properties are often relevant in understanding the response of a material to i...
International audienceWe develop a quantitative model of mechanical repolarization in a contraction-...
Non-pedal forms of locomotion show their advantages in inspection tech-niques or applications to the...
AbstractWith a simple and versatile microcantilever-based force measurement technique, we have probe...
Complex fluids are a broad class of materials that are usually homogeneous at macroscopic scales but...
We study one-dimensional crawlers, namely, model mechanical systems that exploit cyclic shape change...
We study model one-dimensional crawlers, namely, model mechanical systems that can achieve self-prop...
We study model self-propelled crawlers which derive their propulsive capabilities from the tangentia...
We study model locomotors on a substrate, which derive their propulsive capabilities from the tangen...
In this paper we study crawling locomotion based on directional frictional interactions, namely, fri...
We formulate and solve the locomotion problem for a bio-inspired crawler consisting of two active el...
We present experimental and numerical results for a model crawler which is able to extract net posit...
Inspired by the robust locomotion of limbless animals in a range of environments, the development of...
Nonlinear rheological properties are often relevant in understanding the response of a material to i...
International audienceWe develop a quantitative model of mechanical repolarization in a contraction-...
Non-pedal forms of locomotion show their advantages in inspection tech-niques or applications to the...
AbstractWith a simple and versatile microcantilever-based force measurement technique, we have probe...
Complex fluids are a broad class of materials that are usually homogeneous at macroscopic scales but...