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| | <math>f_2 = \frac{\sigma}{2 r_e \lambda}</math> | | | <math>f_2 = \frac{\sigma}{2 r_e \lambda}</math> |
| | <math>f_2 = \frac{2 \pi M_a}{ \rho N_a r_e \lambda^2 } \beta</math> | | | <math>f_2 = \frac{2 \pi M_a}{ \rho N_a r_e \lambda^2 } \beta</math> |
− | | | + | | <math>f_2 = \frac{M_a}{\rho N_a r_e } \mathrm{Im}(\mathrm{SLD})</math> |
| |- | | |- |
| | <math>\sigma = \frac{m_a}{\rho N_a} \frac{1}{\epsilon}</math> | | | <math>\sigma = \frac{m_a}{\rho N_a} \frac{1}{\epsilon}</math> |
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− | | | + | | <math>\mathrm{Im}(\mathrm{SLD}) = \frac{\rho N_a r_e }{M_a} f_2</math> |
| | <math>\mathrm{Im}(\mathrm{SLD}) = \frac{\rho N_a}{2 \lambda M_a}\sigma</math> | | | <math>\mathrm{Im}(\mathrm{SLD}) = \frac{\rho N_a}{2 \lambda M_a}\sigma</math> |
| | <math>\mathrm{Im}(\mathrm{SLD}) = \frac{2 \pi \beta}{\lambda^2} </math> | | | <math>\mathrm{Im}(\mathrm{SLD}) = \frac{2 \pi \beta}{\lambda^2} </math> |
Revision as of 18:12, 6 June 2014
The absorption length or attenuation length in x-ray scattering is the distance over which the x-ray beam is absorbed. By convention, the absorption length ϵ is defined as the distance into a material where the beam flux has dropped to 1/e of its incident flux.
Absorption
The absorption follows a simple Beer-Lambert law:
The attenuation coefficient (or absorption coefficient) is simply the inverse of the absorption length;
Calculating
The absorption length arises from the imaginary part of the atomic scattering factor, f2. It is closely related to the absorption cross-section, and the mass absorption coefficient. Specifically, the atomic photoabsorption cross-section can be computed via:
Where λ is the x-ray wavelength, and re is the classical electron radius. The attenuation coefficient is given by:
where ρ is density, Na is the Avogadro constant, and ma is the atomic molar mass. Note that the mass attenuation coefficient is simply .
Related forms
As can be seen, there are many related quantities which express the material's absorption:
- Absorption length , the distance over which the intensity falls to 1/e.
- Attenuation coefficient , the characteristic inverse-distance for attenuation.
- Mass attenuation coefficient , the density-scaled attenuation.
- Absorptive atomic scattering factor , the intrinsic dissipative interaction of the material.
- Atomic photoabsorption cross-section , the cross-section ('effective size') of the atom's x-ray absorption (capture) efficiency.
- Imaginary refractive index , the resonant component of the refractive index.
- Imaginary Scattering Length Density , the absorptive component of the scattering contrast.
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See Also