Abstract
ATP-driven microtubule-kinesin bundles can self-assemble into two-dimensional active liquid crystals (ALCs) that exhibit a rich creation and annihilation dynamics of topological defects, reminiscent of particle-pair production processes in quantum systems. This recent discovery has sparked considerable interest but a quantitative theoretical description is still lacking. We present and validate a minimal continuum theory for this new class of active matter systems by generalizing the classical Landau–de Gennes free-energy to account for the experimentally observed spontaneous buckling of motor-driven extensile microtubule bundles. The resulting model agrees with recently published data and predicts a regime of antipolar order. Our analysis implies that ALCs are governed by the same generic ordering principles that determine the non-equilibrium dynamics of dense bacterial suspensions and elastic bilayer materials. Moreover, the theory manifests an energetic analogy with strongly interacting quantum gases. Generally, our results suggest that complex nonequilibrium pattern-formation phenomena might be predictable from a few fundamental symmetry-breaking and scale-selection principles.
Highlights
The MIT Faculty has made this article openly available
We hypothesize that the sign change of g2 is directly related to the motor-induced buckling of microtubule bundles (figure 1(a)), an effect that is not captured by the standard Landau–de Gennes (LdG) free-energy for passive liquid crystals
One can regard the free-energy expansion (7) as an effective field theory whose phenomenological parameters can be determined from experiments. This approach has proved successful for dense bacterial suspensions [15, 41] and for active liquid crystal (ALC), suggesting some universality in the formation and dynamics of topological defects in active systems
Summary
The MIT Faculty has made this article openly available. Please share how this access benefits you. This content has been downloaded from IOPscience. 18 093006 (http://iopscience.iop.org/1367-2630/18/9/093006) View the table of contents for this issue, or go to the journal homepage for more. Yeomans Instabilities and chaos in a kinetic equation for active nematics Xia-qing Shi, Hugues Chaté and Yu-qiang Ma Physics of microswimmers—single particle motion and collective behavior: a review J Elgeti, R G Winkler and G Gompper Stressed states and persistent defects in confined nematic elastica M H Köpf and L M Pismen Near equilibrium dynamics and one-dimensional spatial—temporal structures of polar active liquid crystals Yang Xiao-Gang, M. Commons Attribution 3.0 crystals (ALCs) that exhibit a rich creation and annihilation dynamics of topological defects, licence
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