Fluctuation X-ray scattering
Fluctuation X-ray scattering is an X-ray scattering technique similar to small-angle X-ray scattering, but is performed using X-ray exposures below sample rotational diffusion times. This technique, ideally performed with an ultra-bright X-ray light source, such as a free electron laser, results in data containing significantly more information as compared to traditional scattering methods.
FXS can be used for the determination of macromolecular structures, but has also found applications in the characterization of metallic nanostructures, magnetic domains and colloids.
The most general setup of FXS is a situation in which fast diffraction snapshots of models are taken which over a long time period undergo a full 3D rotation. A particularly interesting subclass of FXS is the 2D case where the sample can be viewed as a 2-dimensional system with particles exhibiting random in-plane rotations. In this case, an analytical solution exists relation the FXS data to the structure. In absence of symmetry constraints, no analytical data-to-structure relation for the 3D case is available, although various [|iterative procedures] have been developed.
Overview
An FXS experiment consists of collecting a large number of X-ray snapshots of samples in a different random configuration. By computing angular intensity correlations for each image and averaging these over all snapshots, the average 2-point correlation function can be subjected to a finite Legendre transform, resulting in a collection of so-called Bl curves, where l is the Legendre polynomial order and q / q' the momentum transfer or inverse resolution of the data.Mathematical background
Given a particle with density distribution, the associated three-dimensional complex structure factor is obtained via a Fourier transformThe intensity function corresponding to the complex structure factor is equal to
where denotes complex conjugation. Expressing as a spherical harmonics series, one obtains
The average angular intensity correlation as obtained from many diffraction images is then
It can be shown that
where
with equal to the X-ray wavelength used, and
is a Legendre Polynome. The set of curves can be obtained via a finite Legendre transform from the observed autocorrelation and are thus directly related to the structure via the above expressions.
Additional relations can be obtained by obtaining the real space autocorrelation of the density:
A subsequent expansion of in a spherical harmonics series, results in radial expansion coefficients that are related to the intensity function via a Hankel transform
A concise overview of these relations has been published elsewhere
Basic relations
A generalized Guinier law describing the low resolution behavior of the data can be derived from the above expressions:Values of and can be obtained from a least squares analyses of the low resolution data.
The falloff of the data at higher resolution is governed by Porod laws. It can be shown that the Porod laws derived for SAXS/WAXS data hold here as well, ultimately resulting in:
for particles with well-defined interfaces.