Add to ORKGThe spontaneous emergence of collective flows is a generic property of active fluids and often leads to chaotic flow patterns characterised by swirls, jets, and topological disclinations in their orientation field. However, the ability to achieve structured flows and ordered disclinations is of particular importance in the design and control of active systems. By confining an active nematic fluid within a channel, we find a regular motion of disclinations, in conjunction with a well defined and dynamic vortex lattice. As pairs of moving disclinations travel through the channel, they continually exchange partners producing a dynamic ordered state, reminiscent of Ceilidh dancing. We anticipate that this biomimetic ability to self-assemble org...
Active turbulence describes a flow regime that is erratic, and yet endowed with a characteristic len...
Point-like motile topological defects control the universal dynamics of diverse two-dimensional acti...
Using simulations of self-propelled agents with short-range repulsion and nematic alignment, we expl...
The spontaneous emergence of collective flows is a generic property of active fluids and often leads...
[eng] Living systems flow. What appears obvious from our daily observation of people, birds or insec...
Active matter is based on understanding the physical mechanisms that give rise to large scale flows ...
While studies of active nematics in two dimensions have shed light on various aspects of the flow re...
Active nematic fluids confined in narrow channels generate spontaneous flows when the activity is su...
The physics of active liquid crystals is mostly governed by the interplay between elastic forces tha...
Active matter extracts energy from its surroundings at the single particle level and transforms it i...
This thesis presents analytical and numerical studies of the nonequilibrium dynamics of active nemat...
Groups of animals, bacterial colonies, cellular tissues and assemblies of subcellular extracts are s...
Oscillatory active nematics represent nonequilibrium suspensions of microscopic objects, such as nat...
We study how confinement transforms the chaotic dynamics of bulk microtubule-based active nematics i...
Synthetic active matter is emerging as the prime route for the realisation of biological mechanisms ...
Active turbulence describes a flow regime that is erratic, and yet endowed with a characteristic len...
Point-like motile topological defects control the universal dynamics of diverse two-dimensional acti...
Using simulations of self-propelled agents with short-range repulsion and nematic alignment, we expl...
The spontaneous emergence of collective flows is a generic property of active fluids and often leads...
[eng] Living systems flow. What appears obvious from our daily observation of people, birds or insec...
Active matter is based on understanding the physical mechanisms that give rise to large scale flows ...
While studies of active nematics in two dimensions have shed light on various aspects of the flow re...
Active nematic fluids confined in narrow channels generate spontaneous flows when the activity is su...
The physics of active liquid crystals is mostly governed by the interplay between elastic forces tha...
Active matter extracts energy from its surroundings at the single particle level and transforms it i...
This thesis presents analytical and numerical studies of the nonequilibrium dynamics of active nemat...
Groups of animals, bacterial colonies, cellular tissues and assemblies of subcellular extracts are s...
Oscillatory active nematics represent nonequilibrium suspensions of microscopic objects, such as nat...
We study how confinement transforms the chaotic dynamics of bulk microtubule-based active nematics i...
Synthetic active matter is emerging as the prime route for the realisation of biological mechanisms ...
Active turbulence describes a flow regime that is erratic, and yet endowed with a characteristic len...
Point-like motile topological defects control the universal dynamics of diverse two-dimensional acti...
Using simulations of self-propelled agents with short-range repulsion and nematic alignment, we expl...