2017
DOI: 10.1103/physreve.95.020601
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Long-range nematic order and anomalous fluctuations in suspensions of swimming filamentous bacteria

Abstract: We study the collective dynamics of elongated swimmers in a very thin fluid layer by devising long, filamentous, non-tumbling bacteria. The strong confinement induces weak nematic alignment upon collision, which, for large enough density of cells, gives rise to global nematic order. This homogeneous but fluctuating phase, observed on the largest experimentally-accessible scale of millimeters, exhibits the properties predicted by standard models for flocking such as the Vicsek-style model of polar particles wit… Show more

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Cited by 142 publications
(139 citation statements)
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References 43 publications
(42 reference statements)
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“…We also argue that the ordered nematic phase in both 2d active nematic and self-propelled rod systems must have the same universal description, and hence one cannot have long-ranged nematic order in any locally driven 2d nematic (in the absence of long ranged interactions or hydrodynamics). Reconciling this result with previous numerical and experimental findings of long-ranged nematic order in self-propelled rod systems [12,61] remains a theoretical challenge. By conventional expectations of universality and hydrodynamics, a simple resolution to this question, other than a long crossover, seems to be ruled out at least at the perturbative level.…”
Section: Discussionsupporting
confidence: 59%
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“…We also argue that the ordered nematic phase in both 2d active nematic and self-propelled rod systems must have the same universal description, and hence one cannot have long-ranged nematic order in any locally driven 2d nematic (in the absence of long ranged interactions or hydrodynamics). Reconciling this result with previous numerical and experimental findings of long-ranged nematic order in self-propelled rod systems [12,61] remains a theoretical challenge. By conventional expectations of universality and hydrodynamics, a simple resolution to this question, other than a long crossover, seems to be ruled out at least at the perturbative level.…”
Section: Discussionsupporting
confidence: 59%
“…As the ordered nematic phase of a self-propelled rod system also has only two slow modes (δρ and θ), with the velocity always decaying on a finite time scale, the long distance hydrodynamic description of such a phase is identical to the one discussed here. One would have to verify if the long-ranged order claimed in such systems [12,61] is actually a finite size effect in the sense of Eq. 47, as the phase fluctuations though not finite, grow slower than a logarithm below the crossover scale ξ * , with only much larger systems eventually recovering true QLRO.…”
Section: Perturbative Dynamical Renormalizationmentioning
confidence: 99%
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“…Low-Reynolds-number turbulence is established through continuous energy injection from the constituent elements of an active fluid in many biological systems, including bacterial suspensions123456, cellular monolayers789 or sub-cellular filament/motor protein mixtures1011. Although the inertia is negligible (Reynolds number ≫1) in such systems, active turbulence is characterized by a highly disordered distribution of vortices1213.…”
mentioning
confidence: 99%