Effect of confinement on the mode dynamics of dipole clusters

Schella, André; Melzer, A.; July, Christoph; Bechinger, Clemens

doi:10.1039/c4sm02333a

Cited by 9 publications

(8 citation statements)

References 65 publications

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Order By: Relevance

“…As shown in Fig. 5(b), the relative interparticle distance fluctuations u rel decrease with the increase of the external field, with an amplitude of order similar to that reported for microscopic particles 38 . Further, we observe a clear change in slope of u rel close to the second transition at high field where only intrashell motion occurs.…”

Section: Resultssupporting

confidence: 78%

“…Increasing the applied field, leads to a stronger localization of nanoparticles in the trap and simultaneously strengthens the repulsion between them. In a related context, melting of confined few-body systems has been investigated in experiments 34,35 and numerical simulations [36][37][38] for dipolar particles under hard-wall confinements. However, in contrast to these works, our system is characterized by a nearly harmonic confining potential that can be controlled together with the pairwise interaction.…”

Section: Resultsmentioning

confidence: 99%

“…Further we average it at each time step over all particles. Following a previous work on optically trapped colloidal cluster 54 , to minimize artefacts from the curved frontier we calculate ψ 6 (t) = ψ 6,k , by considering only the particles not adjacent to the outer boundary. Finally, we perform a running-time average and obtain the measure Ψ 6 = ψ 6 (t) for an entire simulation, as shown in Fig.…”

Section: Analysis Of Collective Statesmentioning

confidence: 99%

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Thermally active nanoparticle clusters enslaved by engineered domain wall traps

Tierno

Johansen

Straube

2021

Preprint

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The stable assembly of fluctuating nanoparticle clusters on a surface represents a technological challenge of widespread interest for both fundamental and applied research. Here we demonstrate a technique to stably confine in two dimensions clusters of interacting nanoparticles via size-tunable, virtual magnetic traps. We use cylindrical Bloch walls arranged to form a triangular lattice of ferromagnetic domains within an epitaxially grown ferrite garnet film. At each domain, the magnetic stray field generates an effective harmonic potential with a field tunable stiffness. The experiments are combined with theory to show that the magnetic confinement is effectively harmonic and pairwise interactions are of dipolar nature, leading to central, strictly repulsive forces. For clusters of magnetic nanoparticles, the stationary collective states arise from the competition between repulsion, confinement as the tendency to fill the central potential well. Using a numerical simulation model as a quantitative map between the experiment and theory we explore the field-induced crystallization process for larger clusters and unveil the existence of three different dynamical regimes. The present method provides a model platform for investigations of the collective phenomena emerging when strongly confined nanoparticle clusters are forced to move in an idealized, harmonic-like potential.

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Section: Resultssupporting

confidence: 78%

Section: Resultsmentioning

confidence: 99%

Section: Analysis Of Collective Statesmentioning

confidence: 99%

See 1 more Smart Citation

Thermally active nanoparticle clusters enslaved by engineered domain wall traps

Tierno

Johansen

Straube

2021

Preprint

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show abstract

“…the width of the radial distribution function r R r ( )decreases appreciably due to the radial localization, see figure 10(c). Note that such an ordered arrangement of the APs within the circular pore resembles qualitatively the formation of crystalline clusters in confined paramagnetic colloidal systems [55,56]. In such cases, repulsive dipole-dipole interactions foster classical 2D atomic-like structures composed of concentric shells [57], where the applied magnetic field plays a role similar to the particle activity in our multi-AP system.…”

Section: Circularly Confined Multi-particle Systemmentioning

confidence: 63%

Active particles in geometrically confined viscoelastic fluids

2019

Self Cite

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We experimentally study the dynamics of active particles (APs) in a viscoelastic fluid under various geometrical constraints such as flat walls, spherical obstacles and cylindrical cavities. We observe that the main effect of the confined viscoelastic fluid is to induce an effective repulsion on the APs when moving close to a rigid surface, which depends on the incident angle, the surface curvature and the particle activity. Additionally, the geometrical confinement imposes an asymmetry to their movement, which leads to strong hydrodynamic torques, thus resulting in detention times on the wall surface orders of magnitude shorter than suggested by thermal diffusion. We show that such viscoelasticity-mediated interactions have striking consequences on the behavior of multi-AP systems strongly confined in a circular pore. In particular, these systems exhibit a transition from liquid-like behavior to a highly ordered state upon increasing their activity. A further increase in activity melts the order, thus leading to a re-entrant liquid-like behavior.

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“…Increasing the applied field, leads to a stronger localization of nanoparticles in the trap and simultaneously strengthens the repulsion between them. In a related context, melting of confined few-body systems has been investigated in experiments 36 , 37 and numerical simulations 38 – 40 for dipolar particles under hard-wall confinements. However, in contrast to these works, our system is characterized by a nearly harmonic confining potential that can be controlled together with the pairwise interaction.…”

Section: Resultsmentioning

confidence: 99%

Thermally active nanoparticle clusters enslaved by engineered domain wall traps

2021

View full text Add to dashboard Cite

The stable assembly of fluctuating nanoparticle clusters on a surface represents a technological challenge of widespread interest for both fundamental and applied research. Here we demonstrate a technique to stably confine in two dimensions clusters of interacting nanoparticles via size-tunable, virtual magnetic traps. We use cylindrical Bloch walls arranged to form a triangular lattice of ferromagnetic domains within an epitaxially grown ferrite garnet film. At each domain, the magnetic stray field generates an effective harmonic potential with a field tunable stiffness. The experiments are combined with theory to show that the magnetic confinement is effectively harmonic and pairwise interactions are of dipolar nature, leading to central, strictly repulsive forces. For clusters of magnetic nanoparticles, the stationary collective states arise from the competition between repulsion, confinement and the tendency to fill the central potential well. Using a numerical simulation model as a quantitative map between the experiments and theory we explore the field-induced crystallization process for larger clusters and unveil the existence of three different dynamical regimes. The present method provides a model platform for investigations of the collective phenomena emerging when strongly confined nanoparticle clusters are forced to move in an idealized, harmonic-like potential.

show abstract

Effect of confinement on the mode dynamics of dipole clusters

Cited by 9 publications

References 65 publications

Thermally active nanoparticle clusters enslaved by engineered domain wall traps

Thermally active nanoparticle clusters enslaved by engineered domain wall traps

Active particles in geometrically confined viscoelastic fluids

Thermally active nanoparticle clusters enslaved by engineered domain wall traps

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