Difference between revisions of "Nikhef Higgs InformalDiscussion"

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<font color="blue">'''[Answer: RK]'''</font>
 
<font color="blue">'''[Answer: RK]'''</font>
  
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a good question indeed! In fact there are arguments *against* a nonzero
 
a good question indeed! In fact there are arguments *against* a nonzero
 
v.e.v. for a field with a `mexican hat' potential. This is based on the fact that the
 
v.e.v. for a field with a `mexican hat' potential. This is based on the fact that the

Revision as of 13:15, 29 August 2012

Question: [MM]

How can we possibly experimentally verify that the Higgs particle is a quantum of a field that has a non-zero vacuum expectation value (apart from the theory) ?

If I look in analogy to the pion as a scaler boson: this was the particle describing the strong interaction potential (the Yukawa potential) with a coupling to fermions that is analogous to the Higgs Yukawa couplings (hence the name): psi-bar * psi * phi (psi=fermion field, phi=scalar field). But we never consider assigning a non-zero v.e.v. to the "pion field". So my naieve question is how we ever can experimentally conclude that the Higgs field has a vacuum expectation value?

My dream fantasy would be if there could be some experiment analogous to e.g. the Aharanov-Bohm experiment that shows that in electromagnetism the A-vector-field is physical, even where the B-field is zero. Even a gedanken-experiment would be nice.

[Answer: RK]

a good question indeed! In fact there are arguments *against* a nonzero v.e.v. for a field with a `mexican hat' potential. This is based on the fact that the

  • effective* potential (that is, including all loop corrections) must always be concave, i.e.

bowl-shaped with no bump. If that potential has the same symmetry as the original one, I think the minimum must necessarily lie at phi=0 i.e. no SSB. Of course there are questions about this picture: does it hold for gauges interactions? If there is no SSB then how do we get the particle masses? The concavity argument follows if you believe in path integrals, but not necessarily if you use canonical quantisation - so does that mean that those two approaches are, after all, *not* equivalent? Unfortunately teaching keeps me from attending on 4/9 but I think that these points are still very unsettled, and your suggestion of an A-B type Gedanken experiment is very interesting - ideas, anyone?

[Question: EK] The Higgs field permeates all space: is this true for the entire universe? I know one experimental argument that is based on the observation of distant stars: they emit radiation compatible with spectral lines from a hydrogen atom. This would indicate that at least mass is the same. Is this from theory point of view conclusive evidence? Can we say 'the Higgs field density is uniform' ?