Drell Yan Process: Gamma-Star, Z, and W Mediators

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In summary, the Feynman diagram for Drell Yan has a gamma-star or a Z as the mediator. The gamma-star simply means a photon with a sizable amount of energy, while the Z is a wider resonance with less energy. If a W acts as the mediator, it is still classified as Drell Yan. With a W, you need ##q \bar{q'}## (one up-type and one down-type quark) to produce a Drell Yan process.
  • #1
JoePhysicsNut
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https://particle.phys.uvic.ca/twiki/pub/Main/AlisonFaulkner/Drell-Yan.jpg

The Feynman diagram for Drell Yan has a gamma-star or a Z as the mediator.

Does gamma-star simply mean a photon with a sizeable amount of energy?
Is there a well-defined point in the energy of the mediator when it's a Z instead of a gamma-star? The peak of the Z resonance on an invariant mass plot is 91 GeV, but as a wide resonance it could also have less energy than that.
If a W acts as the mediator, is it still classified as Drell Yan?
 
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Is there a well-defined point in the energy of the mediator when it's a Z instead of a gamma-star? The peak of the Z resonance on an invariant mass plot is 91 GeV, but as a wide resonance it could also have less energy than that.
Fig 4 in this paper shows a nice peak at the Z mass.
 
  • #3
It highlights the fact that the photon is virtual (and therefore off-shell).

Is there a well-defined point in the energy of the mediator when it's a Z instead of a gamma-star?
Both are possible, and their relative contribution depends on the energy of the process.

With a W, you need ##q \bar{q'}## (one up-type and one down-type quark). I don't know how this process is called.
 
  • #4
mfb said:
It highlights the fact that the photon is virtual (and therefore off-shell).

Thank you for your replies!

For massive particles, a real particle is one which lies on mass shell i.e. E^2-p^2*c^2=m^2*c^4. For a virtual particle the equals sign doesn't apply and one can get different values for m other than the true value of m.

However, a photon is massless, so what does it mean for a photon to be off-shell?
 
  • #5
##E \neq p## (or ##E\neq pc## if you don't like c=1) - something which is satisfied for real photons.

Real Photons have the same equation like massive particles, they just have m=0 there.
 
  • #6
JoePhysicsNut said:
Thank you for your replies!

For massive particles, a real particle is one which lies on mass shell i.e. E^2-p^2*c^2=m^2*c^4. For a virtual particle the equals sign doesn't apply and one can get different values for m other than the true value of m.

However, a photon is massless, so what does it mean for a photon to be off-shell?

It also means that for a photon with 4-momentum K, K^2 is NOT 0 as it would be if "on shell".
 
  • #7
If a W acts as the mediator, is it still classified as Drell Yan?
it can not be,can you see why.
 
  • #8
If a W acts as the mediator, is it still classified as Drell Yan?
it can not be,can you see why.
http://theory.fnal.gov/jetp/talks/vicini.pdf on the observation of Drell-Yan processes at the LHC includes in the discussion those in which W is the intermediate particle. Other references use the term "Drell-Yan-like."

EDIT: Especially see the third slide, "The Drell-Yan processes", in which the diagram given has an intermediate W.
 
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  • #9
So a u quark and d(bar) quark annihilate each other.
 
  • #10
Technically, Drell-Yan is only virtual photon exchange. However, especially at high mass, it is indistinguishable from Z exchange, so that is often included. The LHC experiments, by analogy, have called q-qbar annihilation through a virtual W "Drell-Yan", but it is strictly speaking not correct.
 
  • #11
I see from Wikipedia that Drell and Yan described this process in 1970. Electroweak theory (including the Z and W) was just getting off the ground at that time, so it seems natural that (a) they considered only photons, and (b) people later tended to generalize to similar processes involving the other gauge bosons.
 

FAQ: Drell Yan Process: Gamma-Star, Z, and W Mediators

1. What is the Drell Yan process?

The Drell Yan process is a scattering process in high energy particle collisions where a quark and an antiquark annihilate, producing a virtual photon or Z or W boson. These bosons then decay into a pair of leptons (such as electrons or muons) with opposite charges.

2. What are the roles of Gamma-Star, Z, and W mediators in the Drell Yan process?

Gamma-Star, Z, and W mediators are the virtual particles that are exchanged during the Drell Yan process. They carry the weak force and are responsible for the annihilation of the quark and antiquark, as well as the subsequent decay of the virtual boson into a pair of leptons.

3. How is the Drell Yan process related to the Higgs mechanism?

The Higgs mechanism is a theoretical concept that explains how particles acquire mass. In the Drell Yan process, the Z and W bosons are responsible for giving mass to the particles they decay into. This process is a key confirmation of the Higgs mechanism in the Standard Model of particle physics.

4. What are the applications of studying the Drell Yan process?

The Drell Yan process is an important tool for studying the fundamental properties of quarks and leptons, as well as the weak interaction between them. It is also used to search for new particles and interactions beyond the Standard Model. Additionally, the process has practical applications in medical imaging and cancer treatment.

5. How is the Drell Yan process experimentally observed?

The Drell Yan process can be observed in high energy particle collisions, such as those at the Large Hadron Collider (LHC) at CERN. By detecting the decay products of the virtual boson, scientists can reconstruct the process and study its properties. Advanced detectors and data analysis techniques are used to identify and measure the particles involved in the process.

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