Why Is Momentum of One Particle Used in the Breit-Wigner Cross Section Formula?

secret2
Messages
37
Reaction score
0
Is anyone familiar with Breit-Wigner Cross section? Say, for a reaction with 2 particles in the initial state, 1 intermediate and 2 final:

\sigma = \frac{g \pi \lambda^2 \Gamma_i \Gamma_f}{(E-E_0)^2 + \frac{\Gamma^2}{4}}

I can't see why for the wavelength we should use the momentum of EITHER one particle in the initial state. Sure, I can choose either one because in the COM frame it doesn't matter which momentua of the initial particles I choose. But in the derivation of the above equation it is not obvious why the momentum cannot be, say, the TOTAL momentum in the lab frame. Afterall, isn't it true that working in the COM frame is simply a convention?
 
Physics news on Phys.org
Okay.Here's my advice:do the computation if the lab frame.From the very beginning till the end.No reference to COM,whatsoever.And then compare the results...

Yes,it is true.Most (if not all) scattering processes are analyzed using the COM reference frame for ease of calculations and for the fact that the COM is ALWAYS an IRS (elementary,relativistic level)...


Daniel.
 

Thread 'Toponium Discovered'

Toponium is a hadron which is the bound state of a valance top quark and a valance antitop quark. Oversimplified presentations often state that top quarks don't form hadrons, because they decay to bottom quarks extremely rapidly after they are created, leaving no time to form a hadron. And, the vast majority of the time, this is true. But, the lifetime of a top quark is only an average lifetime. Sometimes it decays faster and sometimes it decays slower. In the highly improbable case that...
View full post »

Thread 'Dirac-Delta from Normalization of Continuous Eigenfunctions'

I'm following this paper by Kitaev on SL(2,R) representations and I'm having a problem in the normalization of the continuous eigenfunctions (eqs. (67)-(70)), which satisfy \langle f_s | f_{s'} \rangle = \int_{0}^{1} \frac{2}{(1-u)^2} f_s(u)^* f_{s'}(u) \, du. \tag{67} The singular contribution of the integral arises at the endpoint u=1 of the integral, and in the limit u \to 1, the function f_s(u) takes on the form f_s(u) \approx a_s (1-u)^{1/2 + i s} + a_s^* (1-u)^{1/2 - i s}. \tag{70}...
View full post »

Similar threads

I Understanding how to derive the cross-section formula in the CoM frame
Replies
14
Views
3K
I Are resonances formed in the scattering of a baryon and a meson?
Replies
1
Views
2K
A Dirac Delta Function in Cross Section Formula (Peskin Schroeder QFT)
Replies
1
Views
2K
I Understanding the (polarized) cross section for Compton Scattering by electrons
Replies
4
Views
3K
Breit Wigner Formula & Positron Annihilation
Replies
7
Views
8K
I Cross Section Formula in Peskin and Schroeder
Replies
8
Views
3K
I Why does the trace show up while computing unpolarized cross sections?
Replies
1
Views
1K
I Calculating E+e- -> μ+ μ- Cross Section
Replies
6
Views
2K
I Derivation of splitting function from cross section
Replies
9
Views
3K
A Use of the Optical Theorem and Regge trajectories
Replies
1
Views
2K

Hot Threads

Recent Insights

Back
Top