Hydrodynamic fluctuations in quasi-two dimensional diffusion

Abstract: We study diffusion of colloids on a fluid-fluid interface using particle simulations and fluctuating hydrodynamics. Diffusion on a two-dimensional interface with three-dimensional hydrodynamics is known to be anomalous, with the collective diffusion coefficient diverging like the inverse of the wavenumber. This unusual collective effect arises because of the compressibility of the fluid flow in the plane of the interface, and leads to a nonlinear nonlocal convolution term in the diffusion equation for the ense… Show more

“…Comparisons between DDFT and BD simulations are made frequently. Examples of studies combining DDFT and microscopic simulations consider active particles [20,[296][297][298][299][300], advected DDFT [132], anisotropic pair correlations [286], Brownian aggregation [190,191], canonical dynamics [38], capillary collapse [301], capillary interactions [302], cluster crystallization [244], colloidal fluids in a cavity [272,303], colloidal shaking [294], colloids in a DNA solution [304,305], demixing [306], diffusioncontrolled reactions [307], drag forces [308], driven particles [18,19,[309][310][311], dynamical correlations [312], dynamic mode locking [313], flowing colloids [314], hydrodynamic interactions [41,153,200,210,[315][316][317][318][319][320][321], inhomogeneous polymer systems [322], lane formation [323]…”

“…Regarding applications, the original hydrodynamic DDFTs were used to study sedimentation [133] and oscillations in optical traps [41]. Effects of hydrodynamics in confined systems have also been studied in DDFT [315,316,318,321,405]. Moreover, hydrodynamic DDFT allows to study hydrodynamic interactions in ion diffusion [406], wavenumber-dependent diffusion coefficients [316], crystal growth [189,407], glassy water [209], and velocities of particles subject to hydrodynamic stress [408].…”

Classical dynamical density functional theory: from fundamentals to applications

“…Comparisons between DDFT and BD simulations are made frequently. Examples of studies combining DDFT and microscopic simulations consider active particles [20,[296][297][298][299][300], advected DDFT [132], anisotropic pair correlations [286], Brownian aggregation [190,191], canonical dynamics [38], capillary collapse [301], capillary interactions [302], cluster crystallization [244], colloidal fluids in a cavity [272,303], colloidal shaking [294], colloids in a DNA solution [304,305], demixing [306], diffusioncontrolled reactions [307], drag forces [308], driven particles [18,19,[309][310][311], dynamical correlations [312], dynamic mode locking [313], flowing colloids [314], hydrodynamic interactions [41,153,200,210,[315][316][317][318][319][320][321], inhomogeneous polymer systems [322], lane formation [323]…”

“…Regarding applications, the original hydrodynamic DDFTs were used to study sedimentation [133] and oscillations in optical traps [41]. Effects of hydrodynamics in confined systems have also been studied in DDFT [315,316,318,321,405]. Moreover, hydrodynamic DDFT allows to study hydrodynamic interactions in ion diffusion [406], wavenumber-dependent diffusion coefficients [316], crystal growth [189,407], glassy water [209], and velocities of particles subject to hydrodynamic stress [408].…”

Classical dynamical density functional theory: from fundamentals to applications

Tensiometry and rheology of complex interfaces

Universally Adaptable Multiscale Molecular Dynamics (UAMMD). A native-GPU software ecosystem for complex fluids, soft matter, and beyond