Difference between revisions of "Scattering"
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\mathbf{q} = \begin{bmatrix} q_x & q_y & q_z \end{bmatrix} | \mathbf{q} = \begin{bmatrix} q_x & q_y & q_z \end{bmatrix} | ||
</math> | </math> | ||
− | Consider that the [[x-ray]] beam points along +''y'', so that on the [[detector]], the horizontal is ''x'', and the vertical is ''z''. We assume that the x-ray beam hits the flat 2D area detector at 90° at pixel position <math>\scriptstyle (x,z) </math>. The scattering angles are then: | + | Consider that the [[x-ray]] beam points along +''y'', so that on the [[detector]], the horizontal is ''x'', and the vertical is ''z''. We assume that the x-ray beam hits the flat 2D area detector at 90° at detector (pixel) position <math>\scriptstyle (x,z) </math>. The scattering angles are then: |
:<math> | :<math> | ||
\begin{alignat}{2} | \begin{alignat}{2} | ||
− | \ | + | \theta_f & = \arctan( x/d ) \\ |
− | \ | + | \alpha_f & = \arctan( z/d ) |
\end{alignat} | \end{alignat} | ||
</math> | </math> | ||
− | where <math>\scriptstyle \alpha_f</math> is the out-of-plane component (angle w.r.t. to ''y''-axis, rotation about x-axis), and <math>\scriptstyle \theta_f </math> is the in-plane component (rotation about ''z''-axis). The total scattering angle <math>\scriptstyle 2 \theta = \Theta </math> is related via: | + | where <math>\scriptstyle d</math> is the sample-detector distance, <math>\scriptstyle \alpha_f</math> is the out-of-plane component (angle w.r.t. to ''y''-axis, rotation about x-axis), and <math>\scriptstyle \theta_f </math> is the in-plane component (rotation about ''z''-axis). The total scattering angle <math>\scriptstyle 2 \theta = \Theta </math> is related via: |
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:<math> | :<math> | ||
\begin{alignat}{2} | \begin{alignat}{2} | ||
− | q_x & = \frac{2 \pi}{\ | + | q_x & = \frac{2 \pi}{\lambda} \\ |
− | q_y & = \frac{2 \pi}{\ | + | q_y & = \frac{2 \pi}{\lambda} \\ |
− | q_z & = \frac{2 \pi}{\ | + | q_z & = \frac{2 \pi}{\lambda} |
\end{alignat} | \end{alignat} | ||
</math> | </math> |
Revision as of 16:08, 29 December 2015
Scattering broadly refers to experimental techniques that use the interaction between radiation and matter to elucidate structure. In x-ray scattering, a collimated x-ray beam is directed at a sample of interest. The incident x-rays scatter off of all the atoms/particles in the sample. Because of the wavelike nature of x-rays (which are simply high-energy photons; i.e. electromagnetic rays), the scattered waves interfere with one another, leading to constructive interference at some angles, but destructive interference at other angles. The end result is a pattern of scattered radiation (as a function of angle with respect to the direct beam) that encodes the microscopic, nanoscopic, and molecular-scale structure of the sample.
Contents
Geometry
TSAXS 1D
We define a vector in reciprocal-space as the difference between the incident and scattered x-ray beams. This new vector is the momentum transfer, denoted by q:
The length of this vector is:
Where is the scattering angle.
TSAXS 3D
The q-vector in fact has three components:
Consider that the x-ray beam points along +y, so that on the detector, the horizontal is x, and the vertical is z. We assume that the x-ray beam hits the flat 2D area detector at 90° at detector (pixel) position . The scattering angles are then:
where is the sample-detector distance, is the out-of-plane component (angle w.r.t. to y-axis, rotation about x-axis), and is the in-plane component (rotation about z-axis). The total scattering angle is related via:
And, of course:
Theory
The mathematical form of scattering is closely related to the Fourier transform. The sample's realspace density distribution is Fourier transformed into an abstract 3D reciprocal-space; scattering probes this inverse space. The fundamental equation in scattering is:
Where the observed scattering intensity (I) in the 3D reciprocal-space (q) is given by an ensemble average of the intensity for all (N) scattering entities probed by the beam. The wave-matter interaction is given by inner term, which coherently sums (interferes) the complex scattering contributions ( denotes the scattering power) of the N entities; the exponential term represents a plane wave (incident radiation). In integral form (for a continuous function of the scattering density ), we can write an integral over all of real-space:
The inner component can be thought of as the reciprocal-space:
This is mathematically identical to the (three-dimensional) Fourier transform.