Revision as of 11:50, 24 November 2009 edit Marie Poise (talk \| contribs) 1,723 edits Separate general properties and behaviour for specific systems like gases. Don't number equations as this makes further editing unnecessary complicated. ← Previous edit		Revision as of 15:40, 24 November 2009 edit undo Marie Poise (talk \| contribs) 1,723 edits corr. statement on calculation, link to Ornstein-Zernike equation Next edit →
Line 11: [[File:Lennard-Jones Radial Distribution Function.svg\|thumb\|300px\|Radial distribution function for the [[Lennard–Jones potential\|Lennard-Jones model fluid]] at <math>T^* = 0.71, \; n^* = 0.844</math>.]] Given a [[potential energy]] function, the radial distribution function can be found either via computer simulation methods like the [[Monte Carlo method]]., Itor ~~could~~via ~~also~~the be[[Ornstein-Zernike ~~calculated numerically~~equation]], using ~~rigorous~~approximative ~~methods obtained~~closure ~~from [[statistical mechanics]]~~relations like the [[Perckus-Yevick approximation]], or the [[Hypernetted-chain equation\|Hypernetted Chain Theory]].▼ ▲Given a [[potential energy]] function, the radial distribution function can be found via computer simulation methods like the [[Monte Carlo method]]. It could also be calculated numerically using rigorous methods obtained from [[statistical mechanics]] like the [[Perckus-Yevick approximation]], or the [[Hypernetted-chain equation\|Hypernetted Chain Theory]]. ==Importance of g(r)==

Radial distribution function: Difference between revisions