Add to ORKGChemically active Brownian particles with surface catalytic reactions may repel each other due to diffusiophoretic interactions in the reaction and product concentration fields. The system behavior can be described by a “chemical” coupling parameter Γ_c that compares the strength of diffusiophoretic repulsion to Brownian motion, and by a mapping to the classical electrostatic one component plasma (OCP) system. When confined to a constant-volume domain, body-centered cubic (bcc) crystals spontaneously form from random initial configurations when the repulsion is strong enough to overcome Brownian motion. Face-centered cubic (fcc) crystals may also be stable. The “melting point” of the “liquid-to-crystal transition” occurs at Γ_c ≈ 140 for bo...
We study a system of active particles with soft repulsive interactions that lead to an active cluste...
We derive a microscopic expression for a quantity μ that plays the role of chemical potential of Act...
We derive a microscopic expression for a quantity μ that plays the role of chemical potential of Act...
Chemically active Brownian particles with surface catalytic reactions may repel each other due to di...
Chemically active particles may swim by self-diffusiophoresis in a concentration gradient of chemica...
Diffusiophoresis is the process by which a colloidal particle moves in response to the concentration...
We study the dynamical steady-states of a monolayer of chemically active self-phoretic colloids as a...
A simple theoretical approach is used to investigate active colloids at the free interface and near...
A lattice model is used to study repulsive active particles at a planar surface. A rejection-free K...
We study a two-dimensional system composed by Active Brownian Particles (ABPs), focusing on the onse...
Active colloids exhibit persistent motion, which can lead to motility-induced phase separation (MIPS...
Many motile microorganisms communicate with each other and their environments via chemical signaling...
Many motile microorganisms communicate with each other and their environments via chemical signaling...
We study interacting active Brownian particles (ABPs) with a space-dependent swim velocity via simul...
We study a system of self-propelled disks that perform run-and-tumble motion, where particles can ad...
We study a system of active particles with soft repulsive interactions that lead to an active cluste...
We derive a microscopic expression for a quantity μ that plays the role of chemical potential of Act...
We derive a microscopic expression for a quantity μ that plays the role of chemical potential of Act...
Chemically active Brownian particles with surface catalytic reactions may repel each other due to di...
Chemically active particles may swim by self-diffusiophoresis in a concentration gradient of chemica...
Diffusiophoresis is the process by which a colloidal particle moves in response to the concentration...
We study the dynamical steady-states of a monolayer of chemically active self-phoretic colloids as a...
A simple theoretical approach is used to investigate active colloids at the free interface and near...
A lattice model is used to study repulsive active particles at a planar surface. A rejection-free K...
We study a two-dimensional system composed by Active Brownian Particles (ABPs), focusing on the onse...
Active colloids exhibit persistent motion, which can lead to motility-induced phase separation (MIPS...
Many motile microorganisms communicate with each other and their environments via chemical signaling...
Many motile microorganisms communicate with each other and their environments via chemical signaling...
We study interacting active Brownian particles (ABPs) with a space-dependent swim velocity via simul...
We study a system of self-propelled disks that perform run-and-tumble motion, where particles can ad...
We study a system of active particles with soft repulsive interactions that lead to an active cluste...
We derive a microscopic expression for a quantity μ that plays the role of chemical potential of Act...
We derive a microscopic expression for a quantity μ that plays the role of chemical potential of Act...