Difference between revisions of "Ewald sphere"

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(Definitions)
(GISAXS)
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===[[GISAXS]]===
 
===[[GISAXS]]===
Now let us assume that the incident beam strikes a thin film mounted to a substrate. The incident beam is in the grazing-incidence geometry (e.g. [[GISAXS]], and we denote the angle between the incident beam and the film surface as <math>\theta_i</math>. The reciprocal-space of the sample is thus rotated by <math>\theta_i</math> with respect to the beam reciprocal-space coordinates. We denote the sample's reciprocal coordinate system by uppercase, <math>(Q_x,Q_y,Q_z)</math>, and note that the equation of the Ewald sphere becomes (the center of the sphere is at <math>(0,k \cos\theta_i, k \sin\theta_i)</math>):
+
Now let us assume that the incident beam strikes a thin film mounted to a substrate. The incident beam is in the grazing-incidence geometry (e.g. [[GISAXS]], and we denote the angle between the incident beam and the film surface as <math>\theta_i</math>. The reciprocal-space of the sample is thus rotated by <math>\theta_i</math> with respect to the beam reciprocal-space coordinates. We convert to the sample's reciprocal coordinate space; still denoted by <math>(Q_x,Q_y,Q_z)</math>. The equation of the Ewald sphere becomes (the center of the sphere is at <math>\langle 0,k \cos\theta_i, k \sin\theta_i \rangle</math>):
 
:<math>\begin{alignat}{2}
 
:<math>\begin{alignat}{2}
& Q_x^2 + \left(Q_y-k \cos\theta_i \right)^2 + \left(Q_z-k \sin\theta_i\right)^2 - k^2 = 0 \\
+
& q_x^2 + \left(q_y-k \cos\theta_i \right)^2 + \left(q_z-k \sin\theta_i\right)^2 - k^2 = 0 \\
& Q_y = +k\cos\theta_i  + \sqrt{ k^2 - Q_x^2 - \left(Q_z-k\sin\theta_i\right)^2 }
+
& q_y = +k\cos\theta_i  + \sqrt{ k^2 - q_x^2 - \left(q_z-k\sin\theta_i\right)^2 }
 +
\end{alignat}
 +
</math>
 +
 
 +
===Reflectivity===
 +
Consider for a moment that the ''q''-vector is confined to the <math>(q_y,q_z)</math> plane:
 +
:<math>
 +
\begin{alignat}{2}
 +
\mathbf{q} = \begin{bmatrix}
 +
  0 \\
 +
  - q \sin(\alpha_f - \alpha_i) \\
 +
  + q \cos(\alpha_f - \alpha_i) \\
 +
\end{bmatrix}
 +
\end{alignat}
 +
</math>
 +
Obviously the specular condition is when <math>\alpha_f=\alpha_i</math>, in which case one obtains:
 +
:<math>
 +
\begin{alignat}{2}
 +
\mathbf{q} = \begin{bmatrix}
 +
  0 \\
 +
  0 \\
 +
  + q  \\
 +
\end{bmatrix}
 +
\end{alignat}
 +
</math>
 +
That is, [[reflectivity]] is inherently only probing the out-of-plane (<math>q_z</math>) component:
 +
:<math>
 +
q_z = \frac{4 \pi}{\lambda} \sin \alpha_i
 +
</math>
 +
 
 +
===Out-of-plane scattering only===
 +
Simplifying the above expression yields:
 +
:<math>
 +
\begin{alignat}{2}
 +
\mathbf{q} = \begin{bmatrix}
 +
  0 \\
 +
  - q \sin(\alpha_f - \alpha_i) \\
 +
  + q \cos(\alpha_f - \alpha_i) \\
 +
\end{bmatrix}
 
\end{alignat}
 
\end{alignat}
 
</math>
 
</math>

Revision as of 09:17, 24 June 2014

The Ewald sphere is the surface, in reciprocal-space, that all experimentally-observed scattering arises from. (Strictly, only the elastic scattering comes from the Ewald sphere; inelastic scattering is so-called 'off-shell'.) A peak observed on the detector indicates that a reciprocal-space peak is intersecting with the Ewald sphere.

Mathematics

In TSAXS of an isotropic sample, we only probe the magnitude (not direction) of the momentum transfer:

Where is the full scattering angle. In GISAXS, we must take into account the vector components:

Derivation

Definitions

Consider reciprocal-space in the incident beam coordinate system: . The incident beam is the vector , where:

where is, of course, the wavelength of the incident beam. An elastic scattering event has an outgoing momentum () of the same magnitude as the incident radiation (i.e. ). Consider a momentum vector, and resultant momentum transfer, , of:

The magnitude of the momentum transfer is thus:

where is the full scattering angle. The Ewald sphere is centered about the point and thus has the equation:

TSAXS

In conventional SAXS, the signal of interest is isotropic: i.e. we only care about , and not the individual (directional) components . In such a case we use the form of q derived above:

In the more general case of probing an anisotropic material (e.g. CD-SAXS), one must take into account the full q-vector, and in particular the relative orientation of the incident beam and the sample: i.e. the relative orientation of the Ewald sphere and the reciprocal-space.

GISAXS

Now let us assume that the incident beam strikes a thin film mounted to a substrate. The incident beam is in the grazing-incidence geometry (e.g. GISAXS, and we denote the angle between the incident beam and the film surface as . The reciprocal-space of the sample is thus rotated by with respect to the beam reciprocal-space coordinates. We convert to the sample's reciprocal coordinate space; still denoted by . The equation of the Ewald sphere becomes (the center of the sphere is at ):

Reflectivity

Consider for a moment that the q-vector is confined to the plane:

Obviously the specular condition is when , in which case one obtains:

That is, reflectivity is inherently only probing the out-of-plane () component:

Out-of-plane scattering only

Simplifying the above expression yields:

Literature

Conceptual Understanding of Ewald sphere

Equations of GISAXS Geometry