Soft repulsive mixtures under gravity: Brazil-nut effect, depletion bubbles, boundary layering, nonequilibrium shaking

Kruppa, Tobias; Neuhaus, Tim; Messina, René; Löwen, Hartmut

doi:10.1063/1.3698622

Cited by 10 publications

(20 citation statements)

References 74 publications

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“…Future work should address the dynamics of dipolar mixtures of colloidal particles with different dipole moments [49], where an equilibrium density functional for a binary mixture [50] is needed. These mixtures show more complex possibilities of mixed crystals as a function of the asymmetry in their dipole moments [51].…”

Section: Discussionmentioning

confidence: 99%

Vacancy diffusion in colloidal crystals as determined by dynamical density-functional theory and the phase-field-crystal model

2013

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A two-dimensional crystal of repulsive dipolar particles is studied in the vicinity of its melting transition by using Brownian dynamics computer simulation, dynamical density-functional theory, and phase-field-crystal modeling. A vacancy is created by taking out a particle from an equilibrated crystal, and the relaxation dynamics of the vacancy is followed by monitoring the time-dependent one-particle density. We find that the vacancy is quickly filled up by diffusive hopping of neighboring particles towards the vacancy center. We examine the temperature dependence of the diffusion constant and find that it decreases with decreasing temperature in the simulations. This trend is reproduced by the dynamical density-functional theory. Conversely, the phase-field-crystal calculations predict the opposite trend. Therefore, the phase-field model needs a temperature-dependent expression for the mobility to predict trends correctly.

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Section: Discussionmentioning

confidence: 99%

Vacancy diffusion in colloidal crystals as determined by dynamical density-functional theory and the phase-field-crystal model

2013

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“…Second, the binary magnetic mixture was examined in the nonequilibrium situation of oscillatory gravity, which is a simple model of colloidal shaking. Thereby, Brownian dynamics simulations and dynamic density functional theory were used to study the dynamic response of the system [43]. For other parameters, see Ref.…”

Section: Crystallization At System Boundariesmentioning

confidence: 99%

“…Separation line between the occurrence of the colloidal brazil-nut effect and the absence of this effect in the parameter space of dipolar ratio m and mass ratio M . Monte Carlo simulation data (contoured white squares), density functional data (full black circles) and the transition line implied by the depletion bubble picture (contoured circles) are shown.For other parameters, see Ref [43]…”

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confidence: 99%

Two-dimensional colloidal mixtures in magnetic and gravitational fields

Löwen

Horn

Neuhaus

et al. 2013

Eur. Phys. J. Spec. Top.

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This mini-review is concerned with two-dimensional colloidal mixtures exposed to various kinds of external fields. By a magnetic field perpendicular to the plane, dipole moments are induced in paramagnetic particles which give rise to repulsive interactions leading to complex crystalline alloys in the composition-asymmetry diagram. A quench in the magnetic field induces complex crystal nucleation scenarios. If exposed to a gravitational field, these mixtures exhibit a brazilnut effect and show a boundary layering which is explained in terms of a depletion bubble picture. The latter persists for time-dependent gravity ("colloidal shaking"). Finally, we summarize crystallization effects when the second species is frozen in a disordered matrix which provides obstacles for the crystallizing component.

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“…Thereby, shear deformation constitutes an elementary source of strain. Colloids pose an ideal model system for studying distortions on the particle scale [6] and allow to access the microscopic processes governing structural changes via experiment [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22] and computer simulation [23][24][25][26][27][28][29][30][31][32]. For one-component systems, the plastic deformation of a strained solid is well-explored and a connection between mesoscopic deformation and atomistic rearrangements has been established [33][34][35][36][37][38].…”

Section: Introductionmentioning

confidence: 99%

How does a thermal binary crystal break under shear?

Horn

Löwen

2014

The Journal of Chemical Physics

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When exposed to strong shearing, the particles in a crystal will rearrange and ultimately, the crystal will break by forming large nonaffine defects. Even for the initial stage of this process, only little effort has been devoted to the understanding of the breaking process on the scale of the individual particle size for thermalized mixed crystals. Here, we explore the shear-induced breaking for an equimolar two-dimensional binary model crystal with a high interaction asymmetry between the two different species such that the initial crystal has an intersecting square sublattice of the two constituents. Using Brownian dynamics computer simulations, we show that the combination of shear and thermal fluctuations leads to a characteristic hierarchical breaking scenario where initially, the more strongly coupled particles are thermally distorted, paving the way for the weakly coupled particles to escape from their cage. This in turn leads to mobile defects which may finally merge, proliferating a cascade of defects, which triggers the final breakage of the crystal. This scenario is in marked contrast to the breakage of one-component crystals close to melting. Moreover, we explore the orientational dependence of the initial shear direction relative to the crystal orientation and compare this to the usual melting scenario without shear. Our results are verifiable in real-space experiments of superparamagnetic colloidal mixtures at a pending air-water interface in an external magnetic field where the shear can be induced by an external laser field.

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Soft repulsive mixtures under gravity: Brazil-nut effect, depletion bubbles, boundary layering, nonequilibrium shaking

Cited by 10 publications

References 74 publications

Vacancy diffusion in colloidal crystals as determined by dynamical density-functional theory and the phase-field-crystal model

Vacancy diffusion in colloidal crystals as determined by dynamical density-functional theory and the phase-field-crystal model

Two-dimensional colloidal mixtures in magnetic and gravitational fields

How does a thermal binary crystal break under shear?

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