Add to ORKGIn vitro reconstituted active systems, such as the adenosine triphosphate (ATP)-driven microtubule bundle suspension developed by the Dogic group [T. Sanchez, D. T. Chen, S. J. DeCamp, M. Heymann, and Z. Dogic, Nature (London) 491, 431 (2012)10.1038/nature11591], provide a fertile testing ground for elucidating the phenomenology of active liquid crystalline states. Controlling such novel phases of matter crucially depends on our knowledge of their material and physical properties. In this Rapid Communication, we show that the shear viscosity of an active nematic film can be probed by varying its hydrodynamic coupling to a bounding oil layer. Using the motion of disclinations as intrinsic tracers of the flow field and a hydrodynamic model, w...
The formation of emulsions from multiple immiscible fluids is governed by classical concepts such as...
We present an experimental study of a kinesin/tubulin active nematic formed at different oil interfa...
Active matter is based on understanding the physical mechanisms that give rise to large scale flows ...
In vitro reconstituted active systems, such as the adenosine triphosphate (ATP)-driven microtubule b...
Active liquid crystals are a new class of soft materials that have recently raised a huge interest. ...
Groups of animals, bacterial colonies, cellular tissues and assemblies of subcellular extracts are s...
We conduct our experiments on the microtubule-kinesin active nematic system pioneered in Sanchez et ...
Active matter research is a relatively new and exciting field of study that often merges concepts fr...
We study the dynamics of a tunable 2D active nematic liquid crystal composed of microtubules and kin...
Motor-proteins are responsible for transport inside cells. Harnessing their activity is key towards ...
Active matter extracts energy from its surroundings at the single particle level and transforms it i...
Living cells sense the mechanical features of their environment and adapt to it by actively remodeli...
Coupling between flows and material properties imbues rheological matter with its wide-ranging appli...
Active matter is a field that continues to grow in interest because of its widespread relevance to f...
Coupling between flows and material properties imbues rheological matter with its wide-ranging appli...
The formation of emulsions from multiple immiscible fluids is governed by classical concepts such as...
We present an experimental study of a kinesin/tubulin active nematic formed at different oil interfa...
Active matter is based on understanding the physical mechanisms that give rise to large scale flows ...
In vitro reconstituted active systems, such as the adenosine triphosphate (ATP)-driven microtubule b...
Active liquid crystals are a new class of soft materials that have recently raised a huge interest. ...
Groups of animals, bacterial colonies, cellular tissues and assemblies of subcellular extracts are s...
We conduct our experiments on the microtubule-kinesin active nematic system pioneered in Sanchez et ...
Active matter research is a relatively new and exciting field of study that often merges concepts fr...
We study the dynamics of a tunable 2D active nematic liquid crystal composed of microtubules and kin...
Motor-proteins are responsible for transport inside cells. Harnessing their activity is key towards ...
Active matter extracts energy from its surroundings at the single particle level and transforms it i...
Living cells sense the mechanical features of their environment and adapt to it by actively remodeli...
Coupling between flows and material properties imbues rheological matter with its wide-ranging appli...
Active matter is a field that continues to grow in interest because of its widespread relevance to f...
Coupling between flows and material properties imbues rheological matter with its wide-ranging appli...
The formation of emulsions from multiple immiscible fluids is governed by classical concepts such as...
We present an experimental study of a kinesin/tubulin active nematic formed at different oil interfa...
Active matter is based on understanding the physical mechanisms that give rise to large scale flows ...