Difference between revisions of "Paper:DNA-nanoparticle superlattices formed from anisotropic building blocks"

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(Summary of Mathematics)
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</math>
 
</math>
  
Where the '''structure factor''' is defined by an orientational average (randomly oriented crystal(s)):
+
Where the '''[[structure factor]]''' is defined by an orientational average (randomly oriented crystal(s)):
 
:<math>
 
:<math>
 
S(q) \equiv \left\langle \frac{|F(\mathbf{q})|^2}{P(q)} S(\mathbf{q}) \right\rangle  
 
S(q) \equiv \left\langle \frac{|F(\mathbf{q})|^2}{P(q)} S(\mathbf{q}) \right\rangle  
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</math>
 
</math>
  
The (isotropic) '''form factor intensity''' is an average over all possible particle orientations:
+
The (isotropic) '''[[form factor]] intensity''' is an average over all possible particle orientations:
 
:<math>
 
:<math>
 
\begin{alignat}{2}
 
\begin{alignat}{2}

Revision as of 14:05, 15 October 2014

This is a summary/discussion of the results from:

This paper describes the formation of nanoparticle [[superlattices] from anisotropic nano-objects. In the Supplementary Information information, the authors describe how to model x-ray scattering data from lattices of anisotropic nanoparticles.

Summary of Mathematics

Randomly oriented crystals give scattering intensity:

Where the structure factor is defined by an orientational average (randomly oriented crystal(s)):

and can be computed by:


Where c is a constant, and L is the peak shape; such as:

The (isotropic) form factor intensity is an average over all possible particle orientations:

The form factor amplitude is computed via: