Machine-learned many-body potentials from Poisson-Boltzmann calculations on clusters up to 48 colloids show that higher-order interactions reduce cohesion and eliminate broad gas-liquid phase separation, consistent with primitive model pair and triplet potentials.
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Simulations show fluidized spherical particles in narrow pipes form stable hexagonal cylindrical shells along the wall, sustained mainly by particle-particle contact forces, with stability decreasing as polydispersity increases.
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Many-body attractions do not stabilize gas-liquid phase separation in aqueous dispersions of charged colloids within the Poisson-Boltzmann framework
Machine-learned many-body potentials from Poisson-Boltzmann calculations on clusters up to 48 colloids show that higher-order interactions reduce cohesion and eliminate broad gas-liquid phase separation, consistent with primitive model pair and triplet potentials.
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Formation of cylindrical shells via sphere packing from fluidized beds
Simulations show fluidized spherical particles in narrow pipes form stable hexagonal cylindrical shells along the wall, sustained mainly by particle-particle contact forces, with stability decreasing as polydispersity increases.
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