2018
DOI: 10.1038/s41467-018-06842-6
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Engineering bacterial vortex lattice via direct laser lithography

Abstract: A suspension of swimming bacteria is possibly the simplest realization of active matter, i.e. a class of systems transducing stored energy into mechanical motion. Collective swimming of hydrodynamically interacting bacteria resembles turbulent flow. This seemingly chaotic motion can be rectified by a geometrical confinement. Here we report on self-organization of a concentrated suspension of motile bacteria Bacillus subtilis constrained by two-dimensional (2D) periodic arrays of microscopic vertical pillars. W… Show more

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Cited by 115 publications
(97 citation statements)
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“…Ref. [43] and Fig. 1(a)), however, only topologically trivial bands can appear due to the absence of a sublattice structure; this is why the kagome-lattice structure (as considered here) is crucial for realizing topological active matter.…”
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confidence: 91%
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“…Ref. [43] and Fig. 1(a)), however, only topologically trivial bands can appear due to the absence of a sublattice structure; this is why the kagome-lattice structure (as considered here) is crucial for realizing topological active matter.…”
mentioning
confidence: 91%
“…Our proposal is based on the simplest setup on a flat continuum space with assuming no internal degrees of freedom of active particles. This class of systems is directly relevant to many realistic setups of active systems [39][40][41][42][43] and our design principle is applicable beyond the minimal model proposed here.Emergent effective Hamiltonian for active matter.-To describe collective dynamics of active matter, we use the Toner-Tu equations [44][45][46][47], which are the hydrodynamic equations for active matter with a polar-type interaction:where ρ(r, t) is the density field of active matter and v(r, t) is the local average of velocities of self-propelled particles. Equation (1) presents the equation of continuity.…”
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confidence: 99%
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“…Taken together, concerted experiments and simulations reveal a system in which the interplay of conservative and active stresses can be used to form and control the formation of dynamic patterns. Such patterns can be manipulated by strain and geometry, thereby providing a new avenue to harness the energy of active particles [57][58][59][60][61] for controlled transport at the microscale.…”
Section: Introductionmentioning
confidence: 99%
“…Some vortex arrays are spontaneously formed due to the hydrodynamic interaction between motile cells, as in the case of sperm cells [1], or the actively moving micro-particles can nematically align due to collisions, such as collectively moving microtubules driven by molecular motors [2]. In bacterial suspensions, vortex lattices can form due to hydrodynamic interactions between micro-organisms guided by the walls of the micro-fluidic channels [3], or the vortex lattice can be formed by introducing periodic obstacles (pillars) within the bacterial suspension [4]. Such highly ordered patterns as vortex lattices possess very different transport properties in comparison with disordered chaotic motion.…”
Section: Introductionmentioning
confidence: 99%