Vibration induced by active nematics

Abstract: Active elements in active nematics can impose forces on immersed bodies and move them accordingly. We numerically investigate the vibrational motion of a cantilever beam placed in active nematics. The continuous energy transfer from vortices to the beam results in beam oscillation, whose direction and amplitude depend on the vortex strength, size and position. Referring to the kinetic-energy spectrum, we indicate that both the large- and small-scale vortices are the primary mechanism for the energy transfer be… Show more

“…In addition, considerable efforts have been divested to evaluate other confinement geometries, such as cylinders, 8,26 circular annulus 27 and spherical surfaces (i.e., shells [28][29][30][31] ). Investigating the organization principles in different confinement geometries might reveal general strategies for rational engineering of microfluidic devices 8,[32][33][34] as well as aid in understanding biological hydrodynamics in vivo. 16 Although previous numerical studies on confined active nematics have yielded crucial insights, the diffusion behavior of the passive particles within these systems has received limited attention.…”

“…, shells 28–31 ). Investigating the organization principles in different confinement geometries might reveal general strategies for rational engineering of microfluidic devices 8,32–34 as well as aid in understanding biological hydrodynamics in vivo . 16…”

On particle motion in a confined square domain filled with active fluids

“…In addition, considerable efforts have been divested to evaluate other confinement geometries, such as cylinders, 8,26 circular annulus 27 and spherical surfaces (i.e., shells [28][29][30][31] ). Investigating the organization principles in different confinement geometries might reveal general strategies for rational engineering of microfluidic devices 8,[32][33][34] as well as aid in understanding biological hydrodynamics in vivo. 16 Although previous numerical studies on confined active nematics have yielded crucial insights, the diffusion behavior of the passive particles within these systems has received limited attention.…”

“…, shells 28–31 ). Investigating the organization principles in different confinement geometries might reveal general strategies for rational engineering of microfluidic devices 8,32–34 as well as aid in understanding biological hydrodynamics in vivo . 16…”

On particle motion in a confined square domain filled with active fluids