We study the self-assembly of a system of self-propelled, Lennard-Jones particles using Brownian dynamics simulations. We examine the state diagrams of the system for different rotational diffusion coefficients of the self-propelled motion of the particles. For fast rotational diffusion, the state diagram exhibits a strong similarity to that of the equilibrium Lennard-Jones fluid. As we decrease the rotational diffusion coefficient, the state diagram is slowly transformed. Specifically, the liquid-gas coexistence region is gradually replaced by a highly dynamic percolating network state. We find significant local alignment of the particles in the percolating network state despite the absence of aligning interactions, and propose a simple me...
We investigate the kinetics of self-assembly by means of Brownian dynamics simulation based on a ide...
We report extensive Monte Carlo and event-driven molecular dynamics simulations of a liquid composed...
Active colloids self-organise to a variety of collective states, ranging from highly motile "molecul...
Self-assembly of active particles is believed to play an important role in enabling tomorrow's gener...
The perplexing and intriguing world of biological systems has inaugurated a new research field in st...
Abstract –The structural and dynamical properties of suspensions of self-propelled Brownian particle...
The structural and dynamical properties of suspensions of self-propelled Brownian particles of spher...
A colloidal dispersion consists of small particles called colloids, typically tens of nanometers to ...
We study a three-dimensional system of self-propelled Lennard-Jones particles using Brownian dynamic...
In this thesis, I present numerical simulations that explore the applications of self-propelled part...
In this thesis, we studied active systems in one or two dimensions in which particles are self-prope...
Self-propelled particles (SPPs) are particles who, by themselves, are able to generate persistent mo...
We study the dynamical steady-states of a monolayer of chemically active self-phoretic colloids as a...
Predicting the self-assembly kinetics of particles with anisotropic interactions, such as colloidal ...
Self-propelled colloids are microscopic entities of typical size between a few nanometers to a few m...
We investigate the kinetics of self-assembly by means of Brownian dynamics simulation based on a ide...
We report extensive Monte Carlo and event-driven molecular dynamics simulations of a liquid composed...
Active colloids self-organise to a variety of collective states, ranging from highly motile "molecul...
Self-assembly of active particles is believed to play an important role in enabling tomorrow's gener...
The perplexing and intriguing world of biological systems has inaugurated a new research field in st...
Abstract –The structural and dynamical properties of suspensions of self-propelled Brownian particle...
The structural and dynamical properties of suspensions of self-propelled Brownian particles of spher...
A colloidal dispersion consists of small particles called colloids, typically tens of nanometers to ...
We study a three-dimensional system of self-propelled Lennard-Jones particles using Brownian dynamic...
In this thesis, I present numerical simulations that explore the applications of self-propelled part...
In this thesis, we studied active systems in one or two dimensions in which particles are self-prope...
Self-propelled particles (SPPs) are particles who, by themselves, are able to generate persistent mo...
We study the dynamical steady-states of a monolayer of chemically active self-phoretic colloids as a...
Predicting the self-assembly kinetics of particles with anisotropic interactions, such as colloidal ...
Self-propelled colloids are microscopic entities of typical size between a few nanometers to a few m...
We investigate the kinetics of self-assembly by means of Brownian dynamics simulation based on a ide...
We report extensive Monte Carlo and event-driven molecular dynamics simulations of a liquid composed...
Active colloids self-organise to a variety of collective states, ranging from highly motile "molecul...