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'''Brownian dynamics (BD)''' can be used to describe the motion of [[molecule]]s in molecular [[simulation]]. It is a simplified version of [[Langevin dynamics]] and corresponds to the limit where no average acceleration takes place during the simulation run. This approximation can also be described as '[[overdamping|overdamped]]' Langevin dynamics, or as Langevin dynamics without [[inertia]]. | |||
In [[Langevin dynamics]], the equation of motion is | |||
:<math>M\ddot{X} = - \nabla U(X) - \gamma M\dot{X} + \sqrt{2 \gamma k_B T M} R(t)</math> | |||
where <math>U(X)</math> is the particle interaction potential; <math>\nabla</math> is the gradient operator such that <math>- \nabla U(X)</math> is the force calculated from the particle interaction potentials; the dot is a time derivative such that <math>\dot{X}</math> is the velocity and <math>\ddot{X}</math> is the acceleration; T is the temperature, k<sub>B</sub> is Boltzmann's constant; and <math>R(t)</math> is a delta-correlated stationary Gaussian process with zero-mean, satisfying | |||
:<math>\left\langle R(t) \right\rangle =0</math> | |||
:<math>\left\langle R(t)R(t') \right\rangle = \delta(t-t').</math> | |||
In Brownian dynamics, no acceleration is assumed to take place. Thus, the <math>M\ddot{X}(t)</math> term is neglected, and the sum of these terms is zero. | |||
:<math>0 = - \nabla U(X) - \gamma M\dot{X}+ \sqrt{2 \gamma k_B T M} R(t)</math> | |||
Defining <math>\zeta = \gamma M</math>, and using the [[Einstein relation (kinetic theory)|Einstein relation]], <math>D = k_B T/\zeta</math>, it is often convenient to write the equation as, | |||
:<math>\dot{X}(t) = - \nabla U(X)/\zeta + \sqrt{2 D} R(t).</math> | |||
==See also== | |||
* [[Brownian motion]] | |||
* [[Immersed boundary method]] | |||
==References== | |||
{{reflist}} | |||
==External links== | |||
* [http://www.csc.fi/english/research/sciences/chemistry/courses/gmx2004/Berendsen4.pdf/download Course on Brownian and Langevin Dynamics] | |||
{{physical-chemistry-stub}} | |||
[[Category:Classical mechanics]] | |||
[[Category:Statistical mechanics]] | |||
[[Category:Dynamical systems]] | |||
Revision as of 08:45, 9 December 2013
Brownian dynamics (BD) can be used to describe the motion of molecules in molecular simulation. It is a simplified version of Langevin dynamics and corresponds to the limit where no average acceleration takes place during the simulation run. This approximation can also be described as 'overdamped' Langevin dynamics, or as Langevin dynamics without inertia.
In Langevin dynamics, the equation of motion is
where is the particle interaction potential; is the gradient operator such that is the force calculated from the particle interaction potentials; the dot is a time derivative such that is the velocity and is the acceleration; T is the temperature, kB is Boltzmann's constant; and is a delta-correlated stationary Gaussian process with zero-mean, satisfying
In Brownian dynamics, no acceleration is assumed to take place. Thus, the term is neglected, and the sum of these terms is zero.
Defining , and using the Einstein relation, , it is often convenient to write the equation as,
See also
References
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