Lennard-Jones model: Difference between revisions

Lennard-Jones potential

The Lennard-Jones potential, developed by Sir John Edward Lennard-Jones, is given by

${\displaystyle V(r)=4\epsilon \left[\left({\frac {\sigma }{r}}\right)^{12}-\left({\frac {\sigma }{r}}\right)^{6}\right]}$

where:

• ${\displaystyle V(r)}$ : potential energy of interaction between two particles at a distance r;

• ${\displaystyle \sigma }$ : diameter (length);

• ${\displaystyle \epsilon }$ : well depth (energy)

Reduced units:

• Density, ${\displaystyle \rho ^{*}\equiv \rho \sigma ^{3}}$, where ${\displaystyle \rho =N/V}$ (number of particles ${\displaystyle N}$ divided by the volume ${\displaystyle V}$.)

• Temperature; ${\displaystyle T^{*}\equiv k_{B}T/\epsilon }$, where ${\displaystyle T}$ is the absolute temperature and ${\displaystyle k_{B}}$ is the Boltzmann constant

Argon

The Lennard-Jones parameters for argon are ${\displaystyle \epsilon /k_{B}\approx }$ 119.8 K and ${\displaystyle \sigma \approx }$ 0.3405 nm. (Ref. ?)

This figure was produced using gnuplot with the command:

plot (4*120*((0.34/x)**12-(0.34/x)**6))

Features

Special points:

• ${\displaystyle V(\sigma )=0}$

• Minimum value of ${\displaystyle V(r)}$ at ${\displaystyle r=r_{min}}$;

${\displaystyle {\frac {r_{min}}{\sigma }}=2^{1/6}\simeq 1.12246...}$

Approximations in simulation: truncation and shifting

Related potential models

It is relatively common the use of potential functions given by:

${\displaystyle V(r)=c_{m,n}\epsilon \left[\left({\frac {\sigma }{r}}\right)^{m}-\left({\frac {\sigma }{r}}\right)^{n}\right].}$

with ${\displaystyle m}$ and ${\displaystyle n}$ being positive integer numbers and ${\displaystyle m>n}$, and ${\displaystyle c_{m,n}}$ is chosen to get the minumum value of ${\displaystyle V(r)}$ being ${\displaystyle V_{min}=-\epsilon }$

These forms are usually refered to as m-n Lennard-Jones Potential.

The 9-3 Lennard-Jones interaction potential is often use to model the interaction between the atoms/molecules of a fluid and a continuous solid wall. In (9-3 Lennard-Jones potential) a justification of this use is presented.

Other dimensions

• 1-dimensional case: Lennard-Jones rods.
• 2-dimensional case: Lennard-Jones disks.

References

1. J. E. Lennard-Jones, "Cohesion", Proceedings of the Physical Society, 43 pp. 461-482 (1931)