Flexible molecules: Difference between revisions

Latest revision as of 15:32, 30 July 2007

Modelling of internal degrees of freedom, usual techniques:

Atoms linked by a chemical bond (stretching) using the harmonic spring approximation:

\Phi _{str}(r_{12})={\frac {1}{2}}K_{str}(r_{12}-b_{0})^{2}

However, this internal coordinates are very often kept constrained (fixed bond distances)

Bond sequence: 1-2-3:

Bond Angle: $\left.\theta \right.$

\cos \theta ={\frac {{\vec {r}}_{21}\cdot {\vec {r}}_{23}}{|{\vec {r}}_{21}||{\vec {r}}_{23}|}}

Two typical forms are used to model the bending potential:

\Phi _{bend}(\theta )={\frac {1}{2}}k_{\theta }\left(\theta -\theta _{0}\right)^{2}

\Phi _{bend}(\cos \theta )={\frac {1}{2}}k_{c}\left(\cos \theta -c_{0}\right)^{2}

Bond sequence: 1-2-3-4 Dihedral angle ( $\left.\phi \right.$ ) definition:

Consider the following vectors:

${\vec {a}}\equiv {\frac {{\vec {r}}_{3}-{\vec {r}}_{2}}{|{\vec {r}}_{3}-{\vec {r}}_{2}|}}$ ; Unit vector in the direction of the 2-3 bond

${\vec {b}}\equiv {\frac {{\vec {r}}_{21}-({\vec {r}}_{21}\cdot {\vec {a}}){\vec {a}}}{|{\vec {r}}_{21}-({\vec {r}}_{21}\cdot {\vec {a}}){\vec {a}}|}}$ ; normalized component of ${\vec {r}}_{21}$ ortogonal to ${\vec {a}}$

${\vec {e}}_{34}\equiv {\frac {{\vec {r}}_{34}-({\vec {r}}_{34}\cdot {\vec {a}}){\vec {a}}}{|{\vec {r}}_{34}-({\vec {r}}_{34}\cdot {\vec {a}}){\vec {a}}|}}$ ; normalized component of ${\vec {r}}_{34}$ ortogonal to ${\vec {a}}$

For molecules with internal rotation degrees of freedom (e.g. n-alkanes), a torsional potential is usually modelled as:

$\Phi _{tors}\left(\phi \right)=\sum _{i=0}^{n}a_{i}\left(\cos \phi \right)^{i}$

or

For pairs of atoms (or sites) which are separated by a certain number of chemical bonds:

Pair interactions similar to the typical intermolecular potentials are frequently used (e.g. Lennard-Jones potentials)

@@ Line 2: / Line 2: @@
 == Bond distances ==
-Atoms linked by a chemical bond (stretching):
+Atoms linked by a chemical bond (stretching) using the [[harmonic spring approximation]]:
-<math> \Phi_{str} (r_{12}) = \frac{1}{2} K_{str} ( r_{12} - b_0 )^2 </math>
+:<math> \Phi_{str} (r_{12}) = \frac{1}{2} K_{str} ( r_{12} - b_0 )^2 </math>
 However, this internal coordinates are very often kept constrained (fixed bond distances)
@@ Line 14: / Line 14: @@
 Bond Angle: <math> \left. \theta \right. </math>
-<math> \cos \theta = \frac{ \vec{r}_{21} \cdot \vec{r}_{23} } {|\vec{r}_{21}| |\vec{r}_{23}|}
+:<math> \cos \theta = \frac{ \vec{r}_{21} \cdot \vec{r}_{23} } {|\vec{r}_{21}| |\vec{r}_{23}|}
 </math>
 Two typical forms are used to model the ''bending'' potential:
-<math>
+:<math>
 \Phi_{bend}(\theta) = \frac{1}{2} k_{\theta} \left( \theta - \theta_0 \right)^2
 </math>
-<math>
+:<math>
 \Phi_{bend}(\cos \theta) = \frac{1}{2} k_{c} \left( \cos \theta - c_0 \right)^2
 </math>