Brownian Dynamics is the designated technique to simulate the collective dynamics of colloidal particles suspended in a solution, e.g., the self-assembly of patchy particles. Simulating the rotational dynamics of anisotropic particles by a first-order Langevin equation, however, gives rise to a number of complications, ranging from singularities when using a set of three rotational coordinates to subtle metric and drift corrections. Here, we derive and numerically validate a quaternion-based Rotational Brownian Dynamics algorithm that handles these complications in a simple and elegant way. The extension to hydrodynamic interactions is also discusse
We describe in detail how to implement a coarse-grained hybrid molecular dynamics and stochastic rot...
32 pages and 11 figuresInternational audienceThe efficient computation of the overdamped, random mot...
The self-assembly of nearly rigid proteins into ordered aggregates is well suited for modeling by th...
Brownian Dynamics is the designated technique to simulate the collective dynamics of colloidal parti...
We present an efficient general method to simulate in the Stokesian limit the coupled translational ...
We present an algorithm for performing rigid-body Brownian dynamics that can take into account the h...
We present a method to calculate the fully anisotropic rotational diffusion tensor from molecular dy...
We introduce new Langevin-type equations describing the rotational and translational motion of rigid...
The modeling of complex reaction-diffusion processes in, for instance, cellular biochemical networks...
We report on details of a simulation technique for particles under quasi-static motion determined by...
We introduce new Langevin-type equations describing the rotational and translational motion of rigid...
AbstractWe introduce an unbiased protocol for performing rotational moves in rigid-body dynamics sim...
Recently, a simple scaling argument was introduced that allows us to map, with some precautions, Bro...
The restricted rotational diffusion of an axially symmetric particle is simulated by the Brownian dy...
We present a novel approach to computing the orientation moments and rheological properties of a dil...
We describe in detail how to implement a coarse-grained hybrid molecular dynamics and stochastic rot...
32 pages and 11 figuresInternational audienceThe efficient computation of the overdamped, random mot...
The self-assembly of nearly rigid proteins into ordered aggregates is well suited for modeling by th...
Brownian Dynamics is the designated technique to simulate the collective dynamics of colloidal parti...
We present an efficient general method to simulate in the Stokesian limit the coupled translational ...
We present an algorithm for performing rigid-body Brownian dynamics that can take into account the h...
We present a method to calculate the fully anisotropic rotational diffusion tensor from molecular dy...
We introduce new Langevin-type equations describing the rotational and translational motion of rigid...
The modeling of complex reaction-diffusion processes in, for instance, cellular biochemical networks...
We report on details of a simulation technique for particles under quasi-static motion determined by...
We introduce new Langevin-type equations describing the rotational and translational motion of rigid...
AbstractWe introduce an unbiased protocol for performing rotational moves in rigid-body dynamics sim...
Recently, a simple scaling argument was introduced that allows us to map, with some precautions, Bro...
The restricted rotational diffusion of an axially symmetric particle is simulated by the Brownian dy...
We present a novel approach to computing the orientation moments and rheological properties of a dil...
We describe in detail how to implement a coarse-grained hybrid molecular dynamics and stochastic rot...
32 pages and 11 figuresInternational audienceThe efficient computation of the overdamped, random mot...
The self-assembly of nearly rigid proteins into ordered aggregates is well suited for modeling by th...