Onsager's variational principle yields thermodynamically consistent diffuse-domain models for interfacial hydrodynamics, deformable vesicles with surface viscosity, and active shells by embedding sharp-surface functionals via a diffuse delta density.
Doi,Soft Matter Physics(Oxford University Press, 2013)
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A passivation-activation cycle of phase-separating proteins nucleates a condensate that repels and propels micron-sized colloids at up to 100 μm/s while resisting Brownian motion and external forces.
A hydrodynamic framework shows contractile cross-linker stresses cause mechanically driven heterochromatin phase separation into droplets that wet the nuclear boundary, while active transcription fluctuations drive long-range coherent chromatin motions and deform the droplets.
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Onsager-variational formulation of diffuse-domain methods for computational modeling of microscale fluid-structure interactions
Onsager's variational principle yields thermodynamically consistent diffuse-domain models for interfacial hydrodynamics, deformable vesicles with surface viscosity, and active shells by embedding sharp-surface functionals via a diffuse delta density.
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Propelling catalytic structures using active phase separation
A passivation-activation cycle of phase-separating proteins nucleates a condensate that repels and propels micron-sized colloids at up to 100 μm/s while resisting Brownian motion and external forces.
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Active Hydrodynamic Theory of Euchromatin and Heterochromatin
A hydrodynamic framework shows contractile cross-linker stresses cause mechanically driven heterochromatin phase separation into droplets that wet the nuclear boundary, while active transcription fluctuations drive long-range coherent chromatin motions and deform the droplets.