Add to ORKGWe use continuum simulations to study the impact of anisotropic hydrodynamic friction on the emergent flows of active nematics. We show that, depending on whether the active particles align with or tumble in their collectively self-induced flows, anisotropic friction can result in markedly different patterns of motion. In a flow-aligning regime and at high anisotropic friction, the otherwise chaotic flows are streamlined into flow lanes with alternating directions, reproducing the experimental laning state that has been obtained by interfacing microtubule–motor protein mixtures with smectic liquid crystals. Within a flow-tumbling regime, however, we find that no such laning state is possible. Instead, the synergistic effects of friction ani...
We present an experimental study of a kinesin/tubulin active nematic formed at different oil interfa...
Active nematic fluids confined in narrow channels generate spontaneous flows when the activity is su...
We study the dynamics of a tunable 2D active nematic liquid crystal composed of microtubules and kin...
We study the interplay between flow, structure, and topology in liquid crystals, in both passive and...
Active nematic fluids confined in narrow channels are known to generate spontaneous flows when the a...
Active nematic fluids confined in narrow channels are known to generate spontaneous flows when the a...
Active liquid crystals are a new class of soft materials that have recently raised a huge interest. ...
The flow behavior of (both low molecular weight and polymeric) liquid crystals is strongly affected ...
Motor-proteins are responsible for transport inside cells. Harnessing their activity is key towards ...
Active matter is based on understanding the physical mechanisms that give rise to large scale flows ...
Liquid crystals are elongated molecules with a rich and surprising phase behavior. Nonequilibrium co...
Within the framework of the two-dimensional Ericksen-Leslie model, we explore the effect of geometri...
Most, but not all, liquid crystals tend to align when subject to shear flow, while most nematic poly...
Synthetic active matter is emerging as the prime route for the realisation of biological mechanisms ...
We present an experimental study of a kinesin/tubulin active nematic formed at different oil interfa...
Active nematic fluids confined in narrow channels generate spontaneous flows when the activity is su...
We study the dynamics of a tunable 2D active nematic liquid crystal composed of microtubules and kin...
We study the interplay between flow, structure, and topology in liquid crystals, in both passive and...
Active nematic fluids confined in narrow channels are known to generate spontaneous flows when the a...
Active nematic fluids confined in narrow channels are known to generate spontaneous flows when the a...
Active liquid crystals are a new class of soft materials that have recently raised a huge interest. ...
The flow behavior of (both low molecular weight and polymeric) liquid crystals is strongly affected ...
Motor-proteins are responsible for transport inside cells. Harnessing their activity is key towards ...
Active matter is based on understanding the physical mechanisms that give rise to large scale flows ...
Liquid crystals are elongated molecules with a rich and surprising phase behavior. Nonequilibrium co...
Within the framework of the two-dimensional Ericksen-Leslie model, we explore the effect of geometri...
Most, but not all, liquid crystals tend to align when subject to shear flow, while most nematic poly...
Synthetic active matter is emerging as the prime route for the realisation of biological mechanisms ...
We present an experimental study of a kinesin/tubulin active nematic formed at different oil interfa...
Active nematic fluids confined in narrow channels generate spontaneous flows when the activity is su...
We study the dynamics of a tunable 2D active nematic liquid crystal composed of microtubules and kin...