Add to ORKGMicrotubule-based active fluids exhibit turbulent-like autonomous flows, which are driven by the molecular motor powered motion of filamentous constituents. Controlling active stresses in space and time is an essential prerequisite for controlling the intrinsically chaotic dynamics of extensile active fluids. We design single-headed kinesin molecular motors that exhibit optically enhanced clustering and thus enable precise and repeatable spatial and temporal control of extensile active stresses. Such motors enable rapid, reversible switching between flowing and quiescent states. In turn, spatio-temporal patterning of the active stress controls the evolution of the ubiquitous bend instability of extensile active fluids and determines its cri...
Dynamic lane formation and long-range active nematic alignment is reported using a geometry in which...
Cytoskeletal networks are foundational examples of active matter and central to self-organized struc...
The motion of microscopic objects is strongly affected by their surrounding environment. In quiescen...
Mixtures of filaments and molecular motors form active materials with diverse dynamical behaviors th...
Active matter is a field that continues to grow in interest because of its widespread relevance to f...
Biological systems achieve precise control over ambient fluids through the self-organization of acti...
Biological systems achieve precise control over ambient fluids through the self-organization of acti...
Living systems are capable of locomotion, reconfiguration and replication. To perform these tasks, c...
Dynamic lane formation and long-range active nematic alignment are reported using a geometry in whic...
The cytoskeleton of biological cells relies on a diverse population of motors, filaments, and bindin...
In cellular phenomena, such as cytoplasmic streaming, molecular motors translocate along microtubule...
Biological functions rely on ordered structures and intricately controlled collective dynamics. This...
We conduct our experiments on the microtubule-kinesin active nematic system pioneered in Sanchez et ...
Motor-proteins are responsible for transport inside cells. Harnessing their activity is key towards ...
Kinesin motors can induce a buckling instability in a microtubule with a fixed minus end. Here we sh...
Dynamic lane formation and long-range active nematic alignment is reported using a geometry in which...
Cytoskeletal networks are foundational examples of active matter and central to self-organized struc...
The motion of microscopic objects is strongly affected by their surrounding environment. In quiescen...
Mixtures of filaments and molecular motors form active materials with diverse dynamical behaviors th...
Active matter is a field that continues to grow in interest because of its widespread relevance to f...
Biological systems achieve precise control over ambient fluids through the self-organization of acti...
Biological systems achieve precise control over ambient fluids through the self-organization of acti...
Living systems are capable of locomotion, reconfiguration and replication. To perform these tasks, c...
Dynamic lane formation and long-range active nematic alignment are reported using a geometry in whic...
The cytoskeleton of biological cells relies on a diverse population of motors, filaments, and bindin...
In cellular phenomena, such as cytoplasmic streaming, molecular motors translocate along microtubule...
Biological functions rely on ordered structures and intricately controlled collective dynamics. This...
We conduct our experiments on the microtubule-kinesin active nematic system pioneered in Sanchez et ...
Motor-proteins are responsible for transport inside cells. Harnessing their activity is key towards ...
Kinesin motors can induce a buckling instability in a microtubule with a fixed minus end. Here we sh...
Dynamic lane formation and long-range active nematic alignment is reported using a geometry in which...
Cytoskeletal networks are foundational examples of active matter and central to self-organized struc...
The motion of microscopic objects is strongly affected by their surrounding environment. In quiescen...