Phy5645/Cross Section Relation: Difference between revisions

Revision as of 23:59, 2 September 2013

The differential cross section is related to the scattering amplitude through

${\frac {d\sigma (\theta )}{d\Omega }}=|f_{k}(\theta )|^{2}.$

Since $|f|^{2}=(\Re e\,f)^{2}+(\Im m\,f)^{2}\geq (\Im mf)^{2},$

we obtain

${\frac {d\sigma (\theta )}{d\Omega }}\geq (\Im m[f_{k}(\theta )])^{2}.$

On the other hand, the optical theorem states that

$\sigma ={\frac {4\pi }{k}}\Im m[f_{k}(0)],$

so that

${\frac {d\sigma (0)}{d\Omega }}\geq {\frac {k^{2}\sigma ^{2}}{16\pi ^{2}}}.$

From this, it follows that $\sigma \leq {\frac {4\pi }{k}}{\sqrt {\frac {d\sigma (0)}{d\Omega }}}.$

@@ Line 9: / Line 9: @@
 <math> \frac{d\sigma (\theta)}{d\Omega} \geq (\Im m[f_{k}(\theta)])^{2}.</math>
-On the other hand, from the optical theorem states that
+On the other hand, the optical theorem states that
 <math> \sigma =\frac{4\pi}{k} \Im m[f_{k}(0)],</math>