Glassy Dynamics in Chiral Fluids

Article Chemistry, Physical

Dynamical clustering interrupts motility-induced phase separation in chiral active Brownian particles

Zhan Ma et al.

Summary: This study reveals that a large torque in chiral active particles interrupts the conventional gas-liquid-like motility-induced phase separation and generates a dynamical clustering state.

JOURNAL OF CHEMICAL PHYSICS (2022)

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Review Physics, Condensed Matter

Active Turbulence

Ricard Alert et al.

Summary: Active fluids, such as bacterial suspensions and sperm cells, exhibit complex spatiotemporal flows reminiscent of inertial turbulence. This phenomenon, known as active turbulence, is characterized by power-law scaling and the absence of energy cascades. The emergence of power-law scaling and the self-organized nature of energy injection distinguish active turbulence from inertial turbulence.

ANNUAL REVIEW OF CONDENSED MATTER PHYSICS (2022)

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Article Physics, Multidisciplinary

Symmetry, Thermodynamics, and Topology in Active Matter

Mark J. Bowick et al.

Summary: This article outlines current and emerging directions in active matter research, aiming to provide a pedagogical introduction for newcomers to the field and a road map of open challenges and future directions for established researchers.

PHYSICAL REVIEW X (2022)

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Article Physics, Multidisciplinary

Collective migration reveals mechanical flexibility of malaria parasites

Pintu Patra et al.

Summary: The collective motion of malaria parasites, specifically the Plasmodium sporozoites, is analyzed. It is found that the mechanical flexibility of the sporozoites is favorable for transmission, as it allows for sorting of the parasites based on their curvatures and speeds. Additionally, the vortices formed by the sporozoites exhibit oscillatory breathing due to the storage of motility force in their elastic energy.

NATURE PHYSICS (2022)

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Article Physics, Multidisciplinary

From motility-induced phase-separation to glassiness in dense active matter

Matteo Paoluzzi et al.

Summary: This study investigates the transition between glassy and fluid states in dense active materials, revealing that the mechanisms leading to fluidization in active systems do not have an equilibrium counterpart.

COMMUNICATIONS PHYSICS (2022)

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Article Multidisciplinary Sciences

Odd dynamics of living chiral crystals

Tzer Han Tan et al.

Summary: Researchers have discovered that swimming starfish embryos can spontaneously assemble into chiral crystals that persist for hours. The formation, dynamics, and dissolution of these living crystals are controlled by the hydrodynamic properties and natural development of the embryos. The living chiral crystals exhibit self-sustained chiral oscillations and unconventional deformation response behaviors, providing direct experimental evidence for the role of non-reciprocal interactions between multicellular organisms in non-equilibrium phases of chiral active matter.

NATURE (2022)

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Article Physics, Multidisciplinary

Disordered Collective Motion in Dense Assemblies of Persistent Particles

Yann-Edwin Keta et al.

Summary: We investigate the emergence of nonequilibrium collective motion in disordered nonthermal active matter using simulations. We find that polydispersity stabilizes a homogeneous active liquid characterized by remarkable velocity correlations and irregular turbulent flows. The active fluid undergoes a nonequilibrium glass transition at large density, accompanied by collective motion.

PHYSICAL REVIEW LETTERS (2022)

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Article Physics, Multidisciplinary

Chiral active matter

Benno Liebchen et al.

Summary: The study of chiral active matter focuses on single particle motion and collective phenomena, including vortex arrays, rotating micro-flocks, and states with unusual rheological properties.

EPL (2022)

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Article Mechanics

Active Brownian particle in harmonic trap: exact computation of moments, and re-entrant transition

Debasish Chaudhuri et al.

Summary: By studying active Brownian particles within a harmonic trap, the exact time dependence of moments can be evaluated using a Laplace transform approach. The kurtosis of displacement is calculated, showing differences between active steady state properties and equilibrium Gaussian form. The kurtosis increases with activity to asymptotic saturation, but varies non-monotonically with trap-stiffness, capturing observed active-to-passive re-entrant behavior.

JOURNAL OF STATISTICAL MECHANICS-THEORY AND EXPERIMENT (2021)

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Article Chemistry, Physical

Transport coefficients in dense active Brownian particle systems: mode-coupling theory and simulation results

Julian Reichert et al.

Summary: We discussed the recent advances in developing a mode-coupling theory for the glass transition of two-dimensional systems of active Brownian particles. The theory describes the structural relaxation near the active glass in terms of transient dynamical density correlation functions. The model has been validated through event-driven Brownian dynamics (ED-BD) simulations and shows good agreement with experimental data, providing a better understanding of the dynamics in active particle systems.

EUROPEAN PHYSICAL JOURNAL E (2021)

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Article Physics, Multidisciplinary

Fluctuating hydrodynamics of chiral active fluids

Ming Han et al.

Summary: Active fluids exhibit equilibrium-like properties when their fluctuating and activated degrees of freedom are statistically decoupled. The emergence of a single effective temperature in these systems parameterizes both the equation of state and Boltzmann statistics. By developing a theory for the fluctuating hydrodynamics of these non-equilibrium fluids and validating it through large-scale molecular dynamics simulations, the microscopic origin of odd viscosities and stress fluctuations in parity-violating fluids is illuminated.

NATURE PHYSICS (2021)

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Article Multidisciplinary Sciences

A geometric criterion for the optimal spreading of active polymers in porous media

Christina Kurzthaler et al.

Summary: Efficient navigation through porous environments by swimming microorganisms and microrobots can be optimized by adjusting their run lengths to match the longest straight path available in the porous medium, a criterion termed as the optimal spreading criterion. This criterion unifies results for porous media with different pore sizes and shapes and for run-and-tumble polymers, providing a fundamental principle for achieving optimal transport of active agents in densely-packed biological and environmental settings.

NATURE COMMUNICATIONS (2021)

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Article Multidisciplinary Sciences

Circular swimming motility and disordered hyperuniform state in an algae system

Mingji Huang et al.

Summary: Active matter consists of individually driven units that convert local stored energy into mechanical motion, leading to various nonequilibrium collective phenomena. One of these phenomena, anomalously large density fluctuations, can be greatly suppressed through effective repulsions between cells generated by fluid flow caused by cell swimming. This results in disordered hyperuniform states under a wide range of density conditions and suggests the possibility of using hydrodynamic flow for self-assembly in active matter.

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA (2021)

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Article Multidisciplinary Sciences

Surfactants and rotelles in active chiral fluids

Christian Scholz et al.

Summary: This study explores the behavior of active analogs of surfactants in active chiral fluids, which operate far from equilibrium and exhibit amphiphilic properties different from molecular surfactants due to their activity. By utilizing printed vibrots in experiments, researchers demonstrate the formation of spinning vesicles at interfaces, serving as mixing agents in the chiral fluid.

SCIENCE ADVANCES (2021)

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Article Chemistry, Physical

Tracer dynamics in crowded active-particle suspensions

Julian Reichert et al.

Summary: This study discusses the dynamics of active Brownian particles in crowded environments, analyzing the mean-squared displacement of active and passive tracer particles in both active and passive host systems. The interaction of the tracer particle with the host particles leads to strong memory effects, impacting the dynamic regimes observed. The predictions of the theory are in good agreement with results obtained from simulations, showing various dynamical regimes emerging in dense systems.

SOFT MATTER (2021)

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Article Chemistry, Physical

Emergent vortices and phase separation in systems of chiral active particles with dipolar interactions

Guo-Jun Liao et al.

Summary: Using BD simulations, we investigated the self-organization of a monolayer of chiral active particles with dipolar interactions. Despite performing simulations at high dipolar coupling strength and low density, we observed phenomena such as vortex formation, phase separation, and flocking transitions in the system. We further studied the dynamics of simple ring structures under the impact of self-propulsion to understand the appearance and disappearance of vortices.

SOFT MATTER (2021)

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Article Chemistry, Physical

Inertial effects of self-propelled particles: From active Brownian to active Langevin motion

Hartmut Loewen

JOURNAL OF CHEMICAL PHYSICS (2020)

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Article Physics, Multidisciplinary

Spontaneous Velocity Alignment in Motility-Induced Phase Separation

L. Caprini et al.

PHYSICAL REVIEW LETTERS (2020)

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Article Physics, Multidisciplinary

Active Trap Model

Eric Woillez et al.

PHYSICAL REVIEW LETTERS (2020)

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Article Mechanics

Stability of dancing Volvox

Takuji Ishikawa et al.

JOURNAL OF FLUID MECHANICS (2020)

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Article Physics, Multidisciplinary

Motility-Induced Microphase and Macrophase Separation in a Two-Dimensional Active Brownian Particle System

Claudio B. Caporusso et al.

PHYSICAL REVIEW LETTERS (2020)

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Article Multidisciplinary Sciences

Reconfigurable emergent patterns in active chiral fluids

Bo Zhang et al.

NATURE COMMUNICATIONS (2020)

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Article Physics, Multidisciplinary

Dynamical Crystallites of Active Chiral Particles

Zhi-Feng Huang et al.

PHYSICAL REVIEW LETTERS (2020)

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Article Physics, Multidisciplinary

Autonomously Probing Viscoelasticity in Disordered Suspensions

Clara Abaurrea-Velasco et al.

PHYSICAL REVIEW LETTERS (2020)

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Article Physics, Fluids & Plasmas

Active matter: Quantifying the departure from equilibrium

Elijah Flenner et al.

PHYSICAL REVIEW E (2020)

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Article Chemistry, Physical

Mode-coupling theory for the steady-state dynamics of active Brownian particles

Grzegorz Szamel

JOURNAL OF CHEMICAL PHYSICS (2019)

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Article Multidisciplinary Sciences

Nonequilibrium strongly hyperuniform fluids of circle active particles with large local density fluctuations

Qun-Li Lei et al.

SCIENCE ADVANCES (2019)

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Article Chemistry, Physical

Active particles sense micromechanical properties of glasses

Celia Lozano et al.

NATURE MATERIALS (2019)

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Article Physics, Multidisciplinary

The odd free surface flows of a colloidal chiral fluid

Vishal Soni et al.

NATURE PHYSICS (2019)

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Article Physics, Multidisciplinary

Interrupted Motility Induced Phase Separation in Aligning Active Colloids

Marjolein N. van der Linden et al.

PHYSICAL REVIEW LETTERS (2019)

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Article Physics, Fluids & Plasmas

Active microrheology, Hall effect, and jamming in chiral fluids

C. Reichhardt et al.

PHYSICAL REVIEW E (2019)

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Article Multidisciplinary Sciences

A random first-order transition theory for an active glass

Saroj Kumar Nandi et al.

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA (2018)

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Article Multidisciplinary Sciences

Aggregation-fragmentation and individual dynamics of active clusters

F. Ginot et al.

NATURE COMMUNICATIONS (2018)

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Article Chemistry, Physical

Clustering and phase separation of circle swimmers dispersed in a monolayer

Guo-Jun Liao et al.

SOFT MATTER (2018)

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Article Chemistry, Physical

Helical paths, gravitaxis, and separation phenomena for mass-anisotropic self-propelling colloids: Experiment versus theory

Andrew I. Campbell et al.

JOURNAL OF CHEMICAL PHYSICS (2017)

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Article Multidisciplinary Sciences

Weak synchronization and large-scale collective oscillation in dense bacterial suspensions

Chong Chen et al.

NATURE (2017)

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Article Physics, Multidisciplinary

How active forces influence nonequilibrium glass transitions

Ludovic Berthier et al.

NEW JOURNAL OF PHYSICS (2017)

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Article Physics, Multidisciplinary

Collective Behavior of Chiral Active Matter: Pattern Formation and Enhanced Flocking

Benno Liebchen et al.

PHYSICAL REVIEW LETTERS (2017)

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Article Physics, Fluids & Plasmas

Mode-coupling theory for active Brownian particles

Alexander Liluashvili et al.

PHYSICAL REVIEW E (2017)

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Article Physics, Fluids & Plasmas

Brownian motion of a circle swimmer in a harmonic trap

Soudeh Jahanshahi et al.

PHYSICAL REVIEW E (2017)

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Article Physics, Multidisciplinary

Dynamics of Self-Propelled Janus Particles in Viscoelastic Fluids

Juan Ruben Gomez-Solano et al.

PHYSICAL REVIEW LETTERS (2016)

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Article Physics, Multidisciplinary

Active Particles in Complex and Crowded Environments

Clemens Bechinger et al.

REVIEWS OF MODERN PHYSICS (2016)

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Article Physics, Multidisciplinary

Motility-Driven Glass and Jamming Transitions in Biological Tissues

Dapeng Bi et al.

PHYSICAL REVIEW X (2016)

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Article Physics, Fluids & Plasmas

Theory for the dynamics of dense systems of athermal self-propelled particles

Grzegorz Szamel

PHYSICAL REVIEW E (2016)

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Article Physics, Fluids & Plasmas

Glassy dynamics of athermal self-propelled particles: Computer simulations and a nonequilibrium microscopic theory

Grzegorz Szamel et al.

PHYSICAL REVIEW E (2015)

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Article Physics, Multidisciplinary

Tunable Long Range Forces Mediated by Self-Propelled Colloidal Hard Spheres

Ran Ni et al.

PHYSICAL REVIEW LETTERS (2015)

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Article Physics, Multidisciplinary

Fast-Moving Bacteria Self-Organize into Active Two-Dimensional Crystals of Rotating Cells

Alexander P. Petroff et al.

PHYSICAL REVIEW LETTERS (2015)

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Article Chemistry, Physical

Glancing angle metal evaporation synthesis of catalytic swimming Janus colloids with well defined angular velocity

R. J. Archer et al.

SOFT MATTER (2015)

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Article Chemistry, Physical

Rotating crystals of magnetic Janus colloids

J. Yan et al.

SOFT MATTER (2015)

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Article Multidisciplinary Sciences

Multidimensional stationary probability distribution for interacting active particles

Claudio Maggi et al.

SCIENTIFIC REPORTS (2015)

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Article Physics, Multidisciplinary

Geometry and Topology of Turbulence in Active Nematics

Luca Giomi

PHYSICAL REVIEW X (2015)

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Article Physics, Multidisciplinary

Nonequilibrium Glassy Dynamics of Self-Propelled Hard Disks

Ludovic Berthier

PHYSICAL REVIEW LETTERS (2014)

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Article Physics, Multidisciplinary

When are active Brownian particles and run-and-tumble particles equivalent? Consequences for motility-induced phase separation

M. E. Cates et al.

EPL (2013)

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Article Physics, Multidisciplinary

Non-equilibrium glass transitions in driven and active matter

Ludovic Berthier et al.

NATURE PHYSICS (2013)

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Article Physics, Multidisciplinary

Structure and Dynamics of a Phase-Separating Active Colloidal Fluid

Gabriel S. Redner et al.

PHYSICAL REVIEW LETTERS (2013)

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Article Physics, Multidisciplinary

Circular Motion of Asymmetric Self-Propelling Particles

Felix Kuemmel et al.

PHYSICAL REVIEW LETTERS (2013)

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Article Physics, Multidisciplinary

Dynamical Clustering and Phase Separation in Suspensions of Self-Propelled Colloidal Particles

Ivo Buttinoni et al.

PHYSICAL REVIEW LETTERS (2013)

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Article Physics, Multidisciplinary

Hydrodynamics of soft active matter

M. C. Marchetti et al.

REVIEWS OF MODERN PHYSICS (2013)

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Article Multidisciplinary Sciences

Living Crystals of Light-Activated Colloidal Surfers

Jeremie Palacci et al.

SCIENCE (2013)

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Article Multidisciplinary Sciences

Pushing the glass transition towards random close packing using self-propelled hard spheres

Ran Ni et al.

NATURE COMMUNICATIONS (2013)

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Article Physics, Multidisciplinary

Crystallization in a Dense Suspension of Self-Propelled Particles

Julian Bialke et al.

PHYSICAL REVIEW LETTERS (2012)

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Article Physics, Multidisciplinary

Athermal Phase Separation of Self-Propelled Particles with No Alignment

Yaouen Fily et al.

PHYSICAL REVIEW LETTERS (2012)

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Article Physics, Fluids & Plasmas

Active jamming: Self-propelled soft particles at high density

Silke Henkes et al.

PHYSICAL REVIEW E (2011)

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Article Physics, Multidisciplinary

Swimming with an Image

R. Di Leonardo et al.

PHYSICAL REVIEW LETTERS (2011)

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Article Physics, Fluids & Plasmas

Structural relaxation of polydisperse hard spheres: Comparison of the mode-coupling theory to a Langevin dynamics simulation

F. Weysser et al.

PHYSICAL REVIEW E (2010)

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Article Physics, Multidisciplinary

Collective Motion of Vibrated Polar Disks

Julien Deseigne et al.

PHYSICAL REVIEW LETTERS (2010)

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Article Physics, Multidisciplinary

Direct Measurement of the Flow Field around Swimming Microorganisms

Knut Drescher et al.

PHYSICAL REVIEW LETTERS (2010)

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Review Physics, Condensed Matter

The Mechanics and Statistics of Active Matter

Sriram Ramaswamy

ANNUAL REVIEW OF CONDENSED MATTER PHYSICS, VOL 1 (2010)

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Article Chemistry, Physical

Comparison of structure and transport properties of concentrated hard and soft sphere fluids

Erik Lange et al.

JOURNAL OF CHEMICAL PHYSICS (2009)

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Article Physics, Multidisciplinary

Deformable Self-Propelled Particles

Takao Ohta et al.

PHYSICAL REVIEW LETTERS (2009)

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Article Physics, Multidisciplinary

Dancing Volvox: Hydrodynamic Bound States of Swimming Algae

Knut Drescher et al.

PHYSICAL REVIEW LETTERS (2009)

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Article Physics, Fluids & Plasmas

Dynamics of a Brownian circle swimmer

Sven van Teeffelen et al.

PHYSICAL REVIEW E (2008)

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Article Physics, Multidisciplinary

Statistical mechanics of interacting run-and-tumble bacteria

J. Tailleur et al.

PHYSICAL REVIEW LETTERS (2008)

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Hydrodynamic attraction of swimming microorganisms by surfaces

Allison P. Berke et al.

PHYSICAL REVIEW LETTERS (2008)

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Article Biophysics

Swimming in circles: Motion of bacteria near solid boundaries

E Lauga et al.

BIOPHYSICAL JOURNAL (2006)

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Relaxation in a glassy binary mixture: Comparison of the mode-coupling theory to a Brownian dynamics simulation

E Flenner et al.

PHYSICAL REVIEW E (2005)

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Glassy Dynamics in Chiral Fluids

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