Difference between revisions of "Structure factor"

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Different structure factors describe different spatial arrangements. Random or disordered materials have diffuse structure factors. Well-ordered materials, such as atomic crystals or nanoscale [[superlattices]], have structure factors with well-defined peaks, which encode the layer-spacing of repeating structures (i.e. <math>\scriptstyle S(q)</math> reflects the [[Fourier transform]] of the crystallographic symmetry).
 
Different structure factors describe different spatial arrangements. Random or disordered materials have diffuse structure factors. Well-ordered materials, such as atomic crystals or nanoscale [[superlattices]], have structure factors with well-defined peaks, which encode the layer-spacing of repeating structures (i.e. <math>\scriptstyle S(q)</math> reflects the [[Fourier transform]] of the crystallographic symmetry).
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==Mathematics==
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The [[scattering intensity]] is frequently divided into the contribution from the [[form factor]] (''F'') and structure factor (''S''):
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:<math>
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\begin{alignat}{2}
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I(q) & = \langle |F(\mathbf{q})|^2 S(\mathbf{q}) \rangle \\
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& = P(q) \left\langle \frac{|F(\mathbf{q})|^2}{P(q)} S(\mathbf{q}) \right\rangle \\
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& = P(q)S(q)
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\end{alignat}
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</math>
  
 
==Example Structure Factors==
 
==Example Structure Factors==

Revision as of 14:08, 15 October 2014

The structure factor is an contribution to measured scattering. The structure factor, can be thought of as encoding the structural information about the same: how the constituents are organized, in relation to one another. This can be contrasted with the form factor, which is the scattering coming from the constituents themselves (i.e. their size, shape, and composition).

Different structure factors describe different spatial arrangements. Random or disordered materials have diffuse structure factors. Well-ordered materials, such as atomic crystals or nanoscale superlattices, have structure factors with well-defined peaks, which encode the layer-spacing of repeating structures (i.e. reflects the Fourier transform of the crystallographic symmetry).

Mathematics

The scattering intensity is frequently divided into the contribution from the form factor (F) and structure factor (S):

Example Structure Factors