Generalized Stokes laws for active colloids and their applications

Singh, Rajesh; Adhikari, R.

doi:10.1088/2399-6528/aaab0d

Cited by 28 publications

(59 citation statements)

References 123 publications

(267 reference statements)

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“…We emphasize that this expression is not limited to the translationally invariant Green's function of unbounded flow, 8πη G(r) = (∇ 2 I − ∇∇)r, but holds generally for any Green's function and is both symmetric and positivedefinite [19,20]. The mutual friction tensors decay inversely with distance in an unbounded fluid and more rapidly in the proximity of boundaries.…”

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confidence: 99%

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Direct verification of the fluctuation-dissipation relation in viscously coupled oscillators

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The fluctuation-dissipation relation, a central result in non-equilibrium statistical physics, relates equilibrium fluctuations in a system to its linear response to external forces. Here we provide a direct experimental verification of this relation for viscously coupled oscillators, as realized by a pair of optically trapped colloidal particles. A theoretical analysis, in which interactions mediated by slow viscous flow are represented by non-local friction tensors, matches experimental results and reveals a frequency maximum in the amplitude of the mutual response which is a sensitive function of the trap stiffnesses and the friction tensors. This allows for its location and width to be tuned and suggests the utility of the trap setup for accurate two-point microrheology.The relation between the generalized susceptibility and equilibrium fluctuations of the generalized forces, first obtained for a linear resistive circuit by Nyquist [1] and then proved for any general linear dissipative system by Callen and Welton [2], is a central result in non-equilibrium statistical physics. The relation can be used to infer the intrinsic fluctuations of a system from measurements of its response to external perturbations or, perhaps more startlingly, to predict its response to external perturbations from the character of its intrinsic fluctuations [3]. The fluctuation-dissipation relation is the point of departure for several areas of current research including fluctuation relations [4], relaxation in glasses [5], and response and correlations in active [6] and driven systems [7,8].The first experimental verification of the relation between fluctuation and dissipation was due to Johnson [9], whose investigation of the "thermal agitation of electricity in conductors" provided the motivation for Nyquist's theoretical work [1]. Though the relation has been verified since in systems with conservative couplings, a direct verification in a system where the coupling is entirely dissipative is, to the best of our knowledge, not available. Colloidal particles in a viscous fluid interact through velocity-dependent many-body hydrodynamic forces whose strength, away from boundaries, is inversely proportional to the distance between the particles. The range of these dissipative forces can be made much greater than that of conservative forces such as the DLVO interaction [10,11]. Therefore, it is possible to engineer a situation where the dominant coupling between colloidal particles is the viscous hydrodynamic force and all other interactions are negligibly small. Such systems, then, are ideal for testing the fluctuation-dissipation relation when couplings are purely dissipative.In this Letter, we present a direct verification of the fluctuation-dissipation relation for a pair of optically trapped colloidal particles in water. We measure the equilibrium fluctuations of the distance between the particles and the response of one particle to the sinusoidal motion of another particle. Transforming both correlations and responses to the fr...

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“…The bold-face notation, with Cartesian indices suppressed, is used for both vectors and tensors. In the limit of slow viscous flow in the fluid, the friction tensors can be calculated from the Stokes equation using a variety of methods [16][17][18][19][20]. To leading order the result is…”

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Direct verification of the fluctuation-dissipation relation in viscously coupled oscillators

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“…n ls n la n lt -of rank l,l 1 andl 2; they correspond to symmetric traceless, antisymmetric and trace combinations of the reducible indices. We denote the three irreducible parts by s ( ) V l and the suffixes s = s a t , , are self-explanatory [30,31]. For convenience, we introduce special notations for the s = l a 1 and s = l a 2 coefficients.…”

Section: Brownian Microhydrodynamics Of Active and Passive Spheresmentioning

confidence: 99%

“…By invoking the linearity of the Stokes equations, it can be shown that the contact forces and torques are linear functions of the boundary condition [31]. They are related to linear velocity V m , angular velocity W m and irreducible modes of active slip s ( ) V m l as, In the equation above, we have used the summation convention for repeated particle (n, m) and mode s ( ) l indices.…”

Section: Brownian Microhydrodynamics Of Active and Passive Spheresmentioning

confidence: 99%

“…This reflects the constant consumption of energy that is necessary to maintain the active slip, independent of the state of motion of the sphere. A method for computing the g matrices in terms of the Green's function has been proposed recently [31]. From there it follows that in an unbounded fluid, the g s…”

Section: Brownian Microhydrodynamics Of Active and Passive Spheresmentioning

confidence: 99%

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Filament actuation by an active colloid at low Reynolds number

Laskar

Adhikari

2017

New J. Phys.

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Active colloids and externally actuated semi-flexible filaments provide basic building blocks for designing autonomously motile micro-machines. Here, we show that a passive semi-flexible filament can be actuated and transported by attaching an active colloid to its terminus. We study the dynamics of this assembly when it is free, tethered, or clamped using overdamped equations of motion that explicitly account for active fluid flow and the forces it mediates. Linear states are destabilized by buckling instabilities to produce stable states of non-zero curvature and writhe. We demarcate boundaries of these states in the two-dimensional parameter space representing dimensionless measures of polar and apolar activity. Our proposed assembly can be used as a novel component in the design of micro-machines at low Reynolds number and to study elastic instabilities driven by "follower" forces.

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Fluctuating hydrodynamics of an autophoretic particle near a permeable interface

Turk,

Adhikari,

Singh

2024

J. Fluid Mech.

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We study the autophoretic motion of a spherical active particle interacting chemically and hydrodynamically with its fluctuating environment in the limit of rapid diffusion and slow viscous flow. Then, the chemical and hydrodynamic fields can be expressed in terms of integrals. The resulting boundary-domain integral equations provide a direct way of obtaining the traction on the particle, requiring the solution of linear integral equations. An exact solution for the chemical and hydrodynamic problems is obtained for a particle in an unbounded domain. For motion near boundaries, we provide corrections to the unbounded solutions in terms of chemical and hydrodynamic Green's functions, preserving the dissipative nature of autophoresis in a viscous fluid for all physical configurations. Using this, we give the fully stochastic update equations for the Brownian trajectory of an autophoretic particle in a complex environment. First, we analyse the Brownian dynamics of particles capable of complex motion in the bulk. We then introduce a chemically permeable planar surface of two immiscible liquids in the vicinity of the particle and provide explicit solutions to the chemo-hydrodynamics of this system. Finally, we study the case of an isotropically phoretic particle hovering above an interface as a function of interfacial solute permeability and viscosity contrast.

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Generalized Stokes laws for active colloids and their applications

Cited by 28 publications

References 123 publications

Direct verification of the fluctuation-dissipation relation in viscously coupled oscillators

Direct verification of the fluctuation-dissipation relation in viscously coupled oscillators

Filament actuation by an active colloid at low Reynolds number

Fluctuating hydrodynamics of an autophoretic particle near a permeable interface

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