Hysteresis, reentrance, and glassy dynamics in systems of self-propelled rods

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Hysteresis, reentrance, and glassy dynamics in systems of self-propelled rods

Hui-Shun Kuan, Robert Blackwell, Loren E. Hough, Matthew A. Glaser, and M. D. Betterton

Phys. Rev. E 92, 060501(R) – Published 31 December 2015

Abstract

Nonequilibrium active matter made up of self-driven particles with short-range repulsive interactions is a useful minimal system to study active matter as the system exhibits collective motion and nonequilibrium order-disorder transitions. We studied high-aspect-ratio self-propelled rods over a wide range of packing fractions and driving to determine the nonequilibrium state diagram and dynamic properties. Flocking and nematic-laning states occupy much of the parameter space. In the flocking state, the average internal pressure is high and structural and mechanical relaxation times are long, suggesting that rods in flocks are in a translating glassy state despite overall flock motion. In contrast, the nematic-laning state shows fluidlike behavior. The flocking state occupies regions of the state diagram at both low and high packing fraction separated by nematic-laning at low driving and a history-dependent region at higher driving; the nematic-laning state transitions to the flocking state for both compression and expansion. We propose that the laning-flocking transitions are a type of glass transition that, in contrast to other glass-forming systems, can show fluidization as density increases. The fluid internal dynamics and ballistic transport of the nematic-laning state may promote collective dynamics of rod-shaped micro-organisms.

Received 17 July 2014
Revised 28 July 2015

DOI:https://doi.org/10.1103/PhysRevE.92.060501

Authors & Affiliations

Hui-Shun Kuan

Department of Chemistry and Biochemistry, University of Colorado at Boulder, Boulder, Colorado 80302, USA

Robert Blackwell, Loren E. Hough, Matthew A. Glaser, and M. D. Betterton

Department of Physics, University of Colorado at Boulder, Boulder, Colorado 80302, USA

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Vol. 92, Iss. 6 — December 2015

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Images

Figure 1
Nonequilibrium state diagram and snapshots of self-propelled rods of aspect ratio 40. (a) State diagram as a function of Peclet number and packing fraction. Points indicate parameter sets of simulations. Solid lines indicate boundaries of regions of stability of different initial conditions. $I$ (orange), isotropic state; $F$ (purple), flocking state; NL (green), nematic-laning state; $C$ (pink), crystalline state. Green-purple striping indicates region where both flocking and nematic-laning initial conditions are stable. (b)–(g) Simulation snapshots at indicated packing fraction and Peclet number. Rods are colored by orientation according to the colorwheel. (b) Isotropic. (c) Nematic. (d) Crystal. (e) Flocking. (f) Nematic-laning. (g) Flocking.
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Figure 2
Hysteresis in simulations under expansion, compression, and with an applied field. (a) Simulation snapshots of an expansion run initially in the nematic-laning state at $ϕ = 0.5$ (far left). When the packing fraction reaches 0.4, the system transitions to the flocking state. (b) Simulation snapshots of a compression run initially in the flocking state at $ϕ = 0.34$ (far right). The system remains in the flocking state when compressed. (c) Simulation snapshots of run with applied nematic aligning field beginning in the flocking state at $ϕ = 0.44$ (far left). The applied field breaks up the flock and allows a return to the nematic-laning state after the field is removed (far right). (d) Internal pressure for systems shown in (a)–(c). Blue, initial nematic-laning state as shown in (a); red, initial flocking state as shown in (b); black, system with nematic aligning field as shown in (c).
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Figure 3
Mechanical and structural properties of the nematic-laning and flocking states. (a,b) Internal pressure as a function of packing fraction during expansion (left-pointing triangles) and compression (right-pointing triangles) runs for simulations with varying Peclet number. The black arrows and open circles indicate the initial state of each run. (c) Structure-factor autocorrelation as a function of time for $Pe = 160$ and systems in the laning $(ϕ = 0.44$ , red) and flocking $(ϕ = 0.34$ , blue) states for the peak nearest wave number $k = 2 π / σ$ . The autocorrelation exhibits exponential decay in the nematic-laning state with characteristic time $τ_{c} = 0.10$ and power-law decay in the flocking state with the exponent $α = 0.27$ as indicated. Inset, semilogarithmic plot. (d) Stress-tensor autocorrelation as a function of time for $Pe = 160$ and systems in the nematic-laning $(ϕ = 0.4$ – $0.48)$ and flocking $(ϕ = 0.36$ – $0.38)$ states. Inset, zoomed view of long-time tail.
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Figure 4
Comparison of self-propelled rod and sphere nonequilibrium state diagrams. (a) SPR state diagram from this study as a function of the translational Peclet number. Blue dashed lines show the limits of stability of the nematic-laning state characterized by ballistic transport along the lane. (b) Self-propelled sphere state diagram as a function of the rotational Peclet number, adapted from Fily, Henkes, and Marchetti [37].
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