Biased molecular dynamics

The probability density for a geometric parameter ξ of the system driven by a Hamiltonian:

H(q,p)=T(p)+V(q),\;

with T(p), and V(q) being kinetic, and potential energies, respectively, can be written as:

P(\xi _{i})={\frac {\int \delta {\Big (}\xi (q)-\xi _{i}{\Big )}\exp \left\{-H(q,p)/k_{B}\,T\right\}dq\,dp}{\int \exp \left\{-H(q,p)/k_{B}\,T\right\}dq\,dp}}=\langle \delta {\Big (}\xi (q)-\xi _{i}{\Big )}\rangle _{H}.

The term $\langle X\rangle _{H}$ stands for a thermal average of quantity X evaluated for the system driven by the Hamiltonian H.

If the system is modified by adding a bias potential ${\tilde {V}}(\xi )$ acting only on a selected internal parameter of the system ξ=ξ(q), the Hamiltonian takes a form:

{\tilde {H}}(q,p)=H(q,p)+{\tilde {V}}(\xi ),

and the probability density of ξ in the biased ensemble is:

{\tilde {P}}(\xi _{i})={\frac {\int \delta {\Big (}\xi (q)-\xi _{i}{\Big )}\exp \left\{-{\tilde {H}}(q,p)/k_{B}\,T\right\}dq\,dp}{\int \exp \left\{-{\tilde {H}}(q,p)/k_{B}\,T\right\}dq\,dp}}=\langle \delta {\Big (}\xi (q)-\xi _{i}{\Big )}\rangle _{\tilde {H}}

It can be shown that the biased and unbiased averages are related via a simple formula:

P(\xi _{i})={\tilde {P}}(\xi _{i}){\frac {\exp \left\{{\tilde {V}}(\xi )/k_{B}\,T\right\}}{\langle \exp \left\{{\tilde {V}}(\xi )/k_{B}\,T\right\}\rangle _{\tilde {H}}}}.

More generally, an observable $\langle A\rangle _{H}$ :

\langle A\rangle _{H}={\frac {\int A(q)\exp \left\{-H(q,p)/k_{B}\,T\right\}dq\,dp}{\int \exp \left\{-H(q,p)/k_{B}\,T\right\}dq\,dp}}

can be expressed in terms of thermal averages within the biased ensemble:

\langle A\rangle _{H}={\frac {\langle A(q)\,\exp \left\{{\tilde {V}}(\xi )/k_{B}\,T\right\}\rangle _{\tilde {H}}}{\langle \exp \left\{{\tilde {V}}(\xi )/k_{B}\,T\right\}\rangle _{\tilde {H}}}}.

Simulation methods such as umbrella sampling^[1] use a bias potential to enhance sampling of ξ in regions with low P(ξ_i) such as transition regions of chemical reactions. The correct distributions are recovered afterwards using the equation for $\langle A\rangle _{H}$ above.

A more detailed description of the method can be found in Ref.^[2]. Biased molecular dynamics can be used also to introduce soft geometric constraints in which the controlled geometric parameter is not strictly constant, instead it oscillates in a narrow interval of values.

For a biased molecular dynamics run with Andersen thermostat, one has to:

Set the standard MD-related tags: IBRION=0, TEBEG, POTIM, and NSW
Set MDALGO=11, and choose an appropriate setting for ANDERSEN_PROB
In order to avoid updating of the bias potential, set HILLS_BIN=NSW
Define collective variables in the ICONST-file, and set the STATUS parameter for the collective variables to 5
Define the bias potential in the PENALTYPOT-file

The values of all collective variables for each MD step are listed in the REPORT-file, check the lines after the string Metadynamics.

↑ Cite error: Invalid <ref> tag; no text was provided for refs named Torrie77
↑ Cite error: Invalid <ref> tag; no text was provided for refs named FrenkelSmit

[Torrie77-1] Cite error: Invalid <ref> tag; no text was provided for refs named Torrie77

[FrenkelSmit-2] Cite error: Invalid <ref> tag; no text was provided for refs named FrenkelSmit

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