|
|
| Line 109: |
Line 109: |
| | & + 2 \times T_iR_iR_f^2 F_{-1}F_{-2} | | & + 2 \times T_iR_iR_f^2 F_{-1}F_{-2} |
| | + 2 \times R_i^2T_fR_f F_{-1}F_{+2} | | + 2 \times R_i^2T_fR_f F_{-1}F_{+2} |
| | + | \end{align} |
| | + | </math> |
| | + | |
| | + | ==Breaking into components== |
| | + | The experimental data <math>I_d(q_z)</math> can be broken into contributions from the transmitted channel <math>I_{Tc}(qz)</math> and reflected channel <math>I_{Rc}(qz)</math>: |
| | + | |
| | + | <math> |
| | + | \begin{align} |
| | + | I_d(q_{z}) |
| | + | & = [ T_i^2T_f^2 + R_i^2 + R_f^2 ] I_{Tc}(q_z) + [ T_i^2 R_f^2 + R_i^2 + T_f^2 ] I_{Rc}(q_z) \\ |
| | + | & = |Tc|^2 I_{Tc}(q_z) + |Rc|^2 I_{Rc}(q_z) \\ |
| | + | \end{align} |
| | + | </math> |
| | + | |
| | + | We define the ratio between the channels to be: |
| | + | <math> |
| | + | \begin{align} |
| | + | w |
| | + | & = \frac{ I_{Tc}(q_z) }{ I_{Tc}(q_z) | I_{Rc}(q_z) } |
| | \end{align} | | \end{align} |
| | </math> | | </math> |
Revision as of 11:30, 12 March 2018
DWBA Equation in thin film
Using the notation 
for compactness, the DWBA equation inside a thin film can be written:
Expansion
Terms
If one expands the 
of the DWBA, one obtains 16 terms:
Equation
The equation can thus be expanded as:
Simplification
We can rearrange to:
![{\displaystyle {\begin{aligned}I_{d}(q_{z})=\,\,&T_{i}^{2}T_{f}^{2}|F(+Q_{z1})|^{2}+T_{i}^{2}R_{f}^{2}|F(-Q_{z2})|^{2}+R_{i}^{2}T_{f}^{2}|F(+Q_{z2})|^{2}+R_{i}^{2}R_{f}^{2}|F(-Q_{z1})|^{2}\\&+T_{i}^{2}T_{f}R_{f}F(+Q_{z1})F(-Q_{z2})\\&+T_{i}R_{i}T_{f}^{2}F(+Q_{z1})F(+Q_{z2})+T_{i}R_{i}T_{f}R_{f}F(+Q_{z1})F(-Q_{z1})\\&+T_{i}^{2}T_{f}R_{f}F(+Q_{z1})F(-Q_{z2})\\&+T_{i}R_{i}T_{f}R_{f}F(+Q_{z2})F(-Q_{z2})+T_{i}R_{i}R_{f}^{2}F(-Q_{z1})F(-Q_{z2})\\&+T_{i}R_{i}T_{f}^{2}F(+Q_{z1})F(+Q_{z2})\\&+T_{i}R_{i}T_{f}R_{f}F(+Q_{z2})F(-Q_{z2})+R_{i}^{2}T_{f}R_{f}F(-Q_{z1})F(+Q_{z2})\\&+T_{i}R_{i}T_{f}R_{f}F(+Q_{z1})F(-Q_{z1})\\&+T_{i}R_{i}R_{f}^{2}F(-Q_{z1})F(-Q_{z2})+R_{i}^{2}T_{f}R_{f}F(-Q_{z1})F(+Q_{z2})\\=\,\,&T_{i}^{2}T_{f}^{2}|F(+Q_{z1})|^{2}+T_{i}^{2}R_{f}^{2}|F(-Q_{z2})|^{2}+R_{i}^{2}T_{f}^{2}|F(+Q_{z2})|^{2}+R_{i}^{2}R_{f}^{2}|F(-Q_{z1})|^{2}\\&+2\times T_{i}^{2}T_{f}R_{f}F(+Q_{z1})F(-Q_{z2})\\&+2\times T_{i}R_{i}T_{f}^{2}F(+Q_{z1})F(+Q_{z2})\\&+2\times T_{i}R_{i}T_{f}R_{f}[F(+Q_{z1})F(-Q_{z1})+F(+Q_{z2})F(-Q_{z2})]\\&+2\times T_{i}R_{i}R_{f}^{2}F(-Q_{z1})F(-Q_{z2})\\&+2\times R_{i}^{2}T_{f}R_{f}xF(-Q_{z1})F(+Q_{z2})\\=\,\,&T_{i}^{2}T_{f}^{2}|F(+Q_{z1})|^{2}+T_{i}^{2}R_{f}^{2}|F(-Q_{z2})|^{2}+R_{i}^{2}T_{f}^{2}|F(+Q_{z2})|^{2}+R_{i}^{2}R_{f}^{2}|F(-Q_{z1})|^{2}\\&+2\times T_{i}^{2}T_{f}R_{f}F(+Q_{z1})F(-Q_{z2})+2\times T_{i}R_{i}T_{f}^{2}F(+Q_{z1})F(+Q_{z2})\\&+2\times T_{i}R_{i}T_{f}R_{f}[F(+Q_{z1})F(-Q_{z1})+F(+Q_{z2})F(-Q_{z2})]\\&+2\times T_{i}R_{i}R_{f}^{2}F(-Q_{z1})F(-Q_{z2})+2\times R_{i}^{2}T_{f}R_{f}xF(-Q_{z1})F(+Q_{z2})\\\end{aligned}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/255a3de6b04851277911d2d7c5dd1465af49d540)
We can rewrite in a more compact form using the notation and 
:
![{\displaystyle {\begin{aligned}I_{d}(q_{z})=\,\,&T_{i}^{2}T_{f}^{2}|F_{+1}|^{2}+T_{i}^{2}R_{f}^{2}|F_{-2}|^{2}+R_{i}^{2}T_{f}^{2}|F_{+2}|^{2}+R_{i}^{2}R_{f}^{2}|F_{-1}|^{2}\\&+2\times T_{i}^{2}T_{f}R_{f}F_{+1}F_{-2}+2\times T_{i}R_{i}T_{f}^{2}F_{+1}F_{+2}\\&+2\times T_{i}R_{i}T_{f}R_{f}[F_{+1}F_{-1}+F_{+2}F_{-2}]\\&+2\times T_{i}R_{i}R_{f}^{2}F_{-1}F_{-2}+2\times R_{i}^{2}T_{f}R_{f}F_{-1}F_{+2}\end{aligned}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/938b875c2cb46e82376844f6bf35b4f58fcbca4d)
Breaking into components
The experimental data 
can be broken into contributions from the transmitted channel 
and reflected channel 
:
![{\displaystyle {\begin{aligned}I_{d}(q_{z})&=[T_{i}^{2}T_{f}^{2}+R_{i}^{2}+R_{f}^{2}]I_{Tc}(q_{z})+[T_{i}^{2}R_{f}^{2}+R_{i}^{2}+T_{f}^{2}]I_{Rc}(q_{z})\\&=|Tc|^{2}I_{Tc}(q_{z})+|Rc|^{2}I_{Rc}(q_{z})\\\end{aligned}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/1e2274a01bc72d1352795436b56e6cdf55f2fa33)
We define the ratio between the channels to be:
