Controlling particle penetration and depletion at the wall using Dissipative Particle Dynamics

“…Using an interaction parameter that was too large leads to large density oscillations near the rigid walls. [ 65,66 ]…”

Analyte‐Driven Clustering of Bio‐Conjugated Magnetic Nanoparticles

“…Using an interaction parameter that was too large leads to large density oscillations near the rigid walls. [ 65,66 ]…”

Analyte‐Driven Clustering of Bio‐Conjugated Magnetic Nanoparticles

“…DPD simulation has been proven to serve as a successful method to study soft matters and has accurately captured the physics of functionalized nanoparticles. [47][48][49][50][51][52][53][54][55][56] The details of the DPD simulation technique are presented in the ESI. †…”

Adhesion dynamics of functionalized nanocarriers to endothelial cells: a dissipative particle dynamics study

“…In this work, the walls are separated by a distance D = l z = 23 r c , and we fixed the values of a w = 115 and z c = 0.4 r c . 34 Although, there is a recent study showing how to control the particle penetration at the walls, using explicit walls made up of DPD particles, 46 the implicit force law used here to simulate the wall is strong enough to prevent penetration of the surfaces. The choice of Poiseuille flow to calculate the viscosity arises from the need to match the conditions under which oil is recovered, where an external force is applied to the injected fluid.…”

The viscosity of polyelectrolyte solutions and its dependence on their persistence length, concentration and solvent quality