Emergent ultra–long-range interactions between active particles in hybrid active–inactive systems

Steimel, Joshua; Aragonés, Juan Ignacio; Hu, Helen; Qureshi, Naser; Alexander‐Katz, Alfredo

doi:10.1073/pnas.1520481113

Cited by 30 publications

(32 citation statements)

References 39 publications

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“…Therefore, we also explore the effect of the spinners' activity on the aggregation dynamics by applying different rotational frequencies, Re = 0.1, 0.72 and 3.58, to spinners embedded in passive matrixes of φ A = 0.8. In agreement with our previous observations for the spinner-spinner interaction in passive environments [22,23], we observe there exists a minimum threshold of loading stress, or spinner activity, for the spinner attractive interaction to be important. Spinners rotating at Re smaller than 0.1 do not aggregate.…”

Section: Resultssupporting

confidence: 93%

Aggregation dynamics of active rotating particles in dense passive media

2019

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Active matter systems are able to exhibit emergent non-equilibrium states due to activity-induced effective interactions between the active particles. Here we study the aggregation and dynamical behavior of active rotating particles, spinners, embedded in 2D passive colloidal monolayers, which constitutes one such non-equilibrium process. Using both experiments and simulations we observe aggregation of active particles or spinners whose behavior resembles classical 2D coarsening. The aggregation behavior and spinner attraction depends on the mechanical properties of the passive monolayer and the activity of spinners. Spinner aggregation only occurs when the passive monolayer behaves elastically and when the spinner activity exceeds a minimum activity threshold. Interestingly for the spinner concentrations investigated here, the spinner concentration doesn't seem to change the dynamics of the aggregation behavior. There is also a characteristic cluster size at which the dynamics of spinner aggregation is maximized as drag through the passive monolayer is minimized and the stress applied on the passive medium is maximized. We also show that a ternary mixture of passive particles, co-rotating, and counter-rotating spinners also aggregates into clusters of co and counter-rotating spinners respectively. * These two authors contributed equally † aalexand@mit.edu arXiv:1701.06930v1 [cond-mat.soft]

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Section: Resultssupporting

confidence: 93%

Aggregation dynamics of active rotating particles in dense passive media

2019

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“…5a). The effects of the secondary flow has been attributed to the repulsion between two spheres spinning side-by-side [35,36,46] as well as to an attraction of a single spinner towards a flat wall along the vorticity direction [43]. The stabilisation of the clusters, requires the formation of structures via hydrodynamic interactions at Re ∼ 1.…”

Section: A Inertial Effectsmentioning

confidence: 99%

Hydrodynamic clustering and emergent phase separation of spherical spinners

Shen

Lintuvuori

2020

Phys. Rev. Research

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We study the hydrodynamics of spherical spinners suspended in a Newtonian fluid at inertial regime. We observe a spontaneous condensation of the spinners into particle rich regions, at low but finite particle Reynolds numbers and volume fractions. The particle clusters have a coherent internal dynamics. The spinners form colloidal vortices surrounded by the fluid depleted of the particles. The formation of vortices is observed both in periodic simulation box and when the spinners are confined between two flat walls. The stabilisation of the observed states relies only on hydrodynamic interactions between the spinners and requires a finite amount of inertia. The observations pave the way for the realisation of 3-dimensional spinner materials, where coherent structures and collective dynamics arise only from the rotational motion of the constituents.

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“…Theg eometry of the suspended objects was expected to play asignificant role in determining the detailed features of such dynamic interactions-which could drive the self-assembly of particles into larger structures without any external interventions.Steimel et al considered atwo-dimensional monolayer of passive colloidal particles and showed that the addition of asmall amount of spinning ferromagnetic colloid facilitated attractive long-range interactions between the active colloid and the tracers,aided by the elasticity of the medium. [140] Theinduced particle interaction depended on the spinning frequency and had am inimum actuation timescale below which no attraction was observed. Ther esults showed that active particles could, in the presence of elastic components,i nteract across very long distances without any chemical modification of the environment.…”

Section: Micronscale Systemsmentioning

confidence: 99%

Dynamic Coupling at Low Reynolds Number

Dey

2019

Angew Chem Int Ed

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Collective and emergent behaviors of active colloidal assemblies provide useful insights into the statistical physics of out-of-equilibrium systems. Colloidal suspensions containing microscopic active swimmers have recently been studied with much vigor to understand principles of energy transfer at low Reynolds number conditions. Using molecules of active enzymes and ångström sized organometallic catalysts it has further been demonstrated that energy can be transferred even by molecules to their surroundings, influencing substantially the overall dynamics of the systems. Monitoring the diffusion of non-reacting tracers dispersed in active solutions, it has been shown that the nature of energy transfer in systems containing different swimmers is surprisingly similar - irrespective of their differences in sizes, modes of energy transduction and propulsion strategies. These observations provide motivation not only to characterize reaction generated force fields under complex fluidic environment but also to look for possible similarity in their behavior across multiple length scales. This review discusses research results obtained so far in this direction, highlighting the common features observed regarding dynamic coupling of swimmers with their surroundings. Activity-induced force generation and its collective effects are expected to find wide importance in transport and organization of materials at smaller length scales. Underscoring the nature of reaction generated perturbations, especially under crowded cytosolic conditions, is further likely to advance our knowledge of intracellular mechanics of small molecules during various metabolic processes and chemical transformations.

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Emergent ultra–long-range interactions between active particles in hybrid active–inactive systems

Cited by 30 publications

References 39 publications

Aggregation dynamics of active rotating particles in dense passive media

Aggregation dynamics of active rotating particles in dense passive media

Hydrodynamic clustering and emergent phase separation of spherical spinners

Dynamic Coupling at Low Reynolds Number

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