Stable manifold: Difference between revisions
en>Helpful Pixie Bot m ISBNs (Build KC) |
en>Solomonfromfinland added Category:Manifolds using HotCat |
||
Line 1: | Line 1: | ||
The | The '''pair distribution function''' (PDF) describes the distribution of distances between pairs of particles contained within a given volume. Mathematically, if ''a'' and ''b'' are two particles in a fluid, the PDF of ''b'' with respect to ''a'', denoted by <math>g_{ab}(\vec{r})</math> is the probability of finding the particle ''b'' at the distance <math>\vec{r}</math> from ''a'', with ''a'' taken as the origin of coordinates. | ||
== Overview == | |||
The pair distribution function is used to describe the distribution of objects within a medium (for example, oranges in a crate or nitrogen molecules in a gas cylinder). If the medium is homogeneous (i.e. every spatial location has identical properties), then there is an equal probability density for finding an object at any position <math>\vec{r}</math>: | |||
:<math>p(\vec{r})=1/V</math>, | |||
where <math>V</math> is the volume of the container. On the other hand, the likelihood of finding ''pairs of objects'' at given positions (i.e. the two-body probability density) is not uniform. For example, pairs of hard balls must be separated by at least the diameter of a ball. The pair distribution function <math>g(\vec{r},\vec{r'})</math> is obtained by scaling the two-body probability density function by the total number of objects <math>N</math> and the size of the container: | |||
:<math>g(\vec{r}, \vec{r}') = p(\vec{r},\vec{r}') V^2 \frac{N-1}{N}</math>. | |||
In the common case where the number of objects in the container is large, this simplifies to give: | |||
:<math>g(\vec{r}, \vec{r}') \approx p(\vec{r},\vec{r}') V^2</math>. | |||
== Simple models and general properties == | |||
The simplest possible pair distribution function assumes that all object locations are mutually independent, giving: | |||
:<math>g(\vec{r})=1</math>, | |||
where <math>\vec{r}</math> is the separation between a pair of objects. However, this is inaccurate in the case of hard objects as discussed above, because it does not account for the minimum separation required between objects. The hole-correction (HC) approximation provides a better model: | |||
:<math>g(r) = | |||
\begin{cases} | |||
0,&r<b,\\ | |||
1,&r\geq{}b | |||
\end{cases}, | |||
</math> | |||
where <math>b</math> is the diameter of one of the objects. | |||
Although the HC approximation gives a reasonable description of sparsely packed objects, it breaks down for dense packing. This may be illustrated by considering a box completely filled by identical hard balls so that each ball touches its neighbours. In this case, every pair of balls in the box is separated by a distance of exactly <math>r=nb</math> where <math>n</math> is a positive whole number. The pair distribution for a volume completely filled by hard spheres is therefore a set of [[Dirac delta function]]s of the form: | |||
:<math>g(r)=\sum\limits_i\delta(r-ib)</math>. | |||
Finally, it may be noted that a pair of objects which are separated by a large distance have no influence on each other's position (provided that the container is not completely filled). Therefore, | |||
:<math>\lim\limits_{r\to\infty}g(r) = 1</math>. | |||
In general, a pair distribution function will take a form somewhere between the sparsely packed (HC approximation) and the densely packed (delta function) models, depending on the packing density <math>f</math>. | |||
== Radial pair distributions == | |||
Of special practical importance is the radial pair distribution function, which is independent of orientation. It is a major descriptor for the atomic structure of amorphous materials (glasses, polymers) and liquids. The radial PDF can be calculated directly from physical measurements like [[light scattering]] or [[x-ray powder diffraction]] through the use of [[Fourier Transform]]. | |||
In Statistical Mechanics the PDF is given by the expression: | |||
<math> | |||
g_{ab}(r) = \frac{1}{N_{a} N_b}\sum\limits_{i=1}^{N_a} \sum\limits_{j=1}^{N_b} \langle \delta( \vert \mathbf{r}_{ij} \vert -r)\rangle | |||
</math> | |||
The [http://www.diffpy.org Diffpy] project is used to match crystal structures with PDF data derived from X-ray or neutron diffraction data. | |||
== See also == | |||
* [[Radial distribution function]] | |||
* [[classical-map hypernetted-chain method]] | |||
[[Category:Statistical mechanics]] | |||
[[Category:Condensed matter physics]] |
Revision as of 04:36, 27 April 2013
The pair distribution function (PDF) describes the distribution of distances between pairs of particles contained within a given volume. Mathematically, if a and b are two particles in a fluid, the PDF of b with respect to a, denoted by is the probability of finding the particle b at the distance from a, with a taken as the origin of coordinates.
Overview
The pair distribution function is used to describe the distribution of objects within a medium (for example, oranges in a crate or nitrogen molecules in a gas cylinder). If the medium is homogeneous (i.e. every spatial location has identical properties), then there is an equal probability density for finding an object at any position :
where is the volume of the container. On the other hand, the likelihood of finding pairs of objects at given positions (i.e. the two-body probability density) is not uniform. For example, pairs of hard balls must be separated by at least the diameter of a ball. The pair distribution function is obtained by scaling the two-body probability density function by the total number of objects and the size of the container:
In the common case where the number of objects in the container is large, this simplifies to give:
Simple models and general properties
The simplest possible pair distribution function assumes that all object locations are mutually independent, giving:
where is the separation between a pair of objects. However, this is inaccurate in the case of hard objects as discussed above, because it does not account for the minimum separation required between objects. The hole-correction (HC) approximation provides a better model:
where is the diameter of one of the objects.
Although the HC approximation gives a reasonable description of sparsely packed objects, it breaks down for dense packing. This may be illustrated by considering a box completely filled by identical hard balls so that each ball touches its neighbours. In this case, every pair of balls in the box is separated by a distance of exactly where is a positive whole number. The pair distribution for a volume completely filled by hard spheres is therefore a set of Dirac delta functions of the form:
Finally, it may be noted that a pair of objects which are separated by a large distance have no influence on each other's position (provided that the container is not completely filled). Therefore,
In general, a pair distribution function will take a form somewhere between the sparsely packed (HC approximation) and the densely packed (delta function) models, depending on the packing density .
Radial pair distributions
Of special practical importance is the radial pair distribution function, which is independent of orientation. It is a major descriptor for the atomic structure of amorphous materials (glasses, polymers) and liquids. The radial PDF can be calculated directly from physical measurements like light scattering or x-ray powder diffraction through the use of Fourier Transform.
In Statistical Mechanics the PDF is given by the expression:
The Diffpy project is used to match crystal structures with PDF data derived from X-ray or neutron diffraction data.