Constrained molecular dynamics: Difference between revisions

Revision as of 06:48, 19 July 2022

Constrained molecular dynamics is performed using the SHAKE algorithm.^[1]. In this algorithm, the Lagrangian for the system $\mathcal{L}$ is extended as follows:

{\displaystyle \mathcal{L}^*(\mathbf{q,\dot{q}}) = \mathcal{L}(\mathbf{q,\dot{q}}) + \sum_{i=1}^{r} \lambda_i \sigma_i(q), }

where the summation is over r geometric constraints, $\mathcal{L}^*$ is the Lagrangian for the extended system, and λ_i is a Lagrange multiplier associated with a geometric constraint σ_i:

{\displaystyle \sigma_i(q) = \xi_i({q})-\xi_i \; }

with ξ_i(q) being a geometric parameter and ξ_i is the value of ξ_i(q) fixed during the simulation.

In the SHAKE algorithm, the Lagrange multipliers λ_i are determined in the iterative procedure:

Perform a standard MD step (leap-frog algorithm):
${\displaystyle v^{t+{\Delta}t/2}_i = v^{t-{\Delta}t/2}_i + \frac{a^{t}_i}{m_i} {\Delta}t }$

${\displaystyle q^{t+{\Delta}t}_i = q^{t}_i + v^{t+{\Delta}t/2}_i{\Delta}t }$
Use the new positions q(t+Δt) to compute Lagrange multipliers for all constraints:
${\displaystyle {\lambda}_k= \frac{1}{{\Delta}t^2} \frac{\sigma_k(q^{t+{\Delta}t})}{\sum_{i=1}^N m_i^{-1} \bigtriangledown_i{\sigma}_k(q^{t}) \bigtriangledown_i{\sigma}_k(q^{t+{\Delta}t})} }$
Update the velocities and positions by adding a contribution due to restoring forces (proportional to λ_k):
${\displaystyle v^{t+{\Delta}t/2}_i = v^{t-{\Delta}t/2}_i + \left( a^{t}_i-\sum_k \frac{{\lambda}_k}{m_i} \bigtriangledown_i{\sigma}_k(q^{t}) \right ) {\Delta}t }$

${\displaystyle q^{t+{\Delta}t}_i = q^{t}_i + v^{t+{\Delta}t/2}_i{\Delta}t }$
repeat steps 2-4 until either |σ_i(q)| are smaller than a predefined tolerance (determined by SHAKETOL), or the number of iterations exceeds SHAKEMAXITER.

How to

Geometric constraints are introduced by defining one or more entries with the STATUS parameter set to 0 in the ICONST-file. Constraints can be used within a standard NVT or NpT MD setting introduced by MDALGO=1|2|3. Note that fixing geometric parameters related to lattice vectors is not allowed within an NVT simulation (VASP would terminate with an error message). Constraints can be combined with restraints, time-dependent bias potentials (Metadynamics), monitored coordinates and other elements available within the context of MD.

References

↑ J. P. Ryckaert, G. Ciccotti, and H. J. C. Berendsen, J. Comp. Phys. 23, 327 (1977).

[Ryckaert77-1] J. P. Ryckaert, G. Ciccotti, and H. J. C. Berendsen, J. Comp. Phys. 23, 327 (1977).

[1]

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 <div id="Slowgro"></div>
+== How to ==
+Geometric constraints are introduced by defining one or more entries with the STATUS parameter set to 0 in the {{FILE|ICONST}}-file. Constraints can be used within a standard NVT or NpT MD setting introduced by {{TAG|MDALGO}}=1|2|3. Note that fixing geometric parameters related to lattice vectors is not allowed within an NVT simulation (VASP would terminate with an error message). Constraints can be combined with restraints, time-dependent bias potentials ([[:Category:Metadynamics|Metadynamics]]), monitored coordinates and other elements available within the context of MD.
 == References ==
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-[[Category:Molecular Dynamics]][[Category:Theory]][[Category:Howto]]
+[[Category:Molecular dynamics]][[Category:Constrained molecular dynamics]][[Category:Theory]][[Category:Howto]]