Generalized Archimedes' principle in active fluids

Nitzan Razin; Raphael Voituriez; Jens Elgeti; Nir S. Gov

doi:10.1103/PhysRevE.96.032606

Generalized Archimedes' principle in active fluids

Nitzan Razin
, Raphael Voituriez
, Jens Elgeti
, Nir S. Gov

Weizmann Institute of Science Israel
Laboratoire Jean Perrin
Research Centre Julich

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We show how a gradient in the motility properties of noninteracting pointlike active particles can cause a pressure gradient that pushes a large inert object. We calculate the force on an object inside a system of active particles with position-dependent motion parameters, in one and two dimensions, and show that a modified Archimedes' principle is satisfied. We characterize the system, both in terms of the model parameters and in terms of experimentally measurable quantities: the spatial profiles of the density, velocity and pressure. This theoretical analysis is motivated by recent experiments, which showed that the nucleus of a mouse oocyte (immature egg cell) moves from the cortex to the center due to a gradient of activity of vesicles propelled by molecular motors; it more generally applies to artificial systems of controlled localized activity.

langue originale	Anglais
Numéro d'article	032606
journal	Physical Review E
Volume	96
Numéro de publication	3
Les DOIs	https://doi.org/10.1103/PhysRevE.96.032606
état	Publié - 15 sept. 2017
Modification externe	Oui

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10.1103/PhysRevE.96.032606

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title = "Generalized Archimedes' principle in active fluids",

abstract = "We show how a gradient in the motility properties of noninteracting pointlike active particles can cause a pressure gradient that pushes a large inert object. We calculate the force on an object inside a system of active particles with position-dependent motion parameters, in one and two dimensions, and show that a modified Archimedes' principle is satisfied. We characterize the system, both in terms of the model parameters and in terms of experimentally measurable quantities: the spatial profiles of the density, velocity and pressure. This theoretical analysis is motivated by recent experiments, which showed that the nucleus of a mouse oocyte (immature egg cell) moves from the cortex to the center due to a gradient of activity of vesicles propelled by molecular motors; it more generally applies to artificial systems of controlled localized activity.",

author = "Nitzan Razin and Raphael Voituriez and Jens Elgeti and Gov, \{Nir S.\}",

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AB - We show how a gradient in the motility properties of noninteracting pointlike active particles can cause a pressure gradient that pushes a large inert object. We calculate the force on an object inside a system of active particles with position-dependent motion parameters, in one and two dimensions, and show that a modified Archimedes' principle is satisfied. We characterize the system, both in terms of the model parameters and in terms of experimentally measurable quantities: the spatial profiles of the density, velocity and pressure. This theoretical analysis is motivated by recent experiments, which showed that the nucleus of a mouse oocyte (immature egg cell) moves from the cortex to the center due to a gradient of activity of vesicles propelled by molecular motors; it more generally applies to artificial systems of controlled localized activity.

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ER -

Generalized Archimedes' principle in active fluids

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