Is the Higgs boson already discovered?

In summary, Alberto Palma's recent paper Arxiv:1202.0217 presents first results of the direct search for the SM Higgs boson, with no evidence found in a pp collision data sample. Upper limits on the Higgs boson production cross section were determined, but it is not yet conclusive if the Higgs boson has been discovered. The most recent news in this area is that the Higgs boson may be living at around 126 GeV, but this is not yet a true detection and more data is needed. Introducing mass directly to the equation in a field-theoretic model would make it non-renormalizable due to the lack of gauge invariance. Non-renormalizable theories are not
  • #1
Ruslan_Sharipov
104
1
Alberto Palma's recent paper Arxiv:1202.0217 says in its conclusions part: "The ATLAS collaboration presents first results of the direct search for the SM Higgs boson decaying to [itex]b\bar b[/itex]. No evidence of the Higgs boson was found in a [itex]pp[/itex] collision data sample of [itex]\mathcal L=1.04\ \mathrm f\mathrm b^{-1}[/itex] at [itex]\sqrt{s}=7\ \mathrm T\mathrm e\mathrm V[/itex]. Instead, upper limits on the Higgs boson production cross section of between 10 and 20 times the SM value were determined, in a mass range [itex]110<m_H<130\ \mathrm G\mathrm e\mathrm V[/itex]".

Does it mean that the Higgs boson is already discovered or not yet? What is the exact meaning of these words? What are the most recent news in this area?
 
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  • #2
My understanding is that the folks at CERN think they have probably discovered the Higgs but the results are not yet conclusive and any announcement would be premature at this point. What they definitely HAVE done is refine the range of possible values for the mass for the Higgs if it does exist.
 
  • #3
The current trend is we think the Higgs is living somewhere at ~126 GeV, see:

http://arxiv.org/abs/1202.1408

But the statistical significance of this is low enough that we shouldn't (and cannot) declare it to be a true detection.

The paper you cite is looking at an (I believe) more difficult decay channel, and is using less data. Plus, it looks like they've only set a bound at ~2sigma.
 
  • #4
Ruslan_Sharipov said:
Does it mean that the Higgs boson is already discovered or not yet? What is the exact meaning of these words? What are the most recent news in this area?

The important sentence in your quote is "No evidence of the Higgs boson was found." They looked, but they didn't see it. However they weren't able to rule out its existence if it has a mass between 110 and 130 GeV. If the Higgs boson does exist and has a mass in this range, they expected not to see it. Note that this is only reporting the result of one particular method of searching for the Higgs. Other searches, which look at other possible decay products, have produced hints (not proof) that the Higgs exists and has a mass around 125 GeV.
 
  • #5
Hi, without invoking higgs, the electroweak is said to be non-renormalizable because one has to introduce mass directly to it. Can anyone please explain briefly why introducing mass directly to the equation would make it non-renormalizable? Thanks.
 
  • #6
Concerning renormalizability, I have heard the following proposition: "A field-theoretic model is renormalizable if and only if its Lagrangian is of the degree not higher than 4 with respect to the fields involved". I don't know its proof and I would like to ask someone more competent than me here: is this proposition true or not?
 
  • #7
The main point is that in order to have a consistent theory with gauge bosons (or generally, vector bosons) , you need to have a symmetry which is called gauge invariance. This symmetry doen't exist if you introduce masses to the gauge bosons. Why do you need this symmetry?
An inspection leads to that a massless vector boson (spin 1 particle) has two degrees of freedom (for exmaple ,a photon has two polarizations) and a massive has three degrees of freedom. However, to introduce a vector boson to your theory in a lorentz invariant way, you have to use an object which is a lorentz vector A_{μ}, which has 4 degrees of freedom. Therefore, some of them are not physical and the gauge invariance makes sure they don't contribute to physical observables. If you would introduce masses directly to the vector bosons , these degrees of freedom would behave badly at high energies, producing results which make no sense( probabilities not summing into one...)
New degrees of freedom are required to cancel this bad behaviour( in the SM case, its the higgs), which are exactly the degrees of freedom which restore the gauge invariance.
In that sense, introducing a mass directly results in a theory which makes sense only up to an energy scale which these new degrees of freedom are required. similar to a standard non renormalizable theory which is a valid only up to a certain cut off scale.
For the standard model without the higgs, this cut off scale is about 800GeV, meaning some new degrees of freedom have to exist up to that scale( the higgs or something else)
Hope that helps
 
  • #8
The original papers which discovered that massive gauge bosons lead to nonrenormalizable theories are listed in reference 13 of http://arxiv.org/abs/hep-ph/0401010. Studying their arguments might be a good way to learn about renormalization technicalities, because there are many subtle details. For example, you can have a massive abelian gauge boson; it's massive nonabelian gauge bosons which lead to a nonrenormalizable theory, because they contain some extra interactions (and thus extra divergences) not present in the abelian case. Also, as often happens in QFT, it seems there is no absolute proof of nonrenormalizability - as late as Veltman's paper in 1968, he's emphasizing that renormalizing the theory will be difficult but maybe not impossible - it seems that everyone gave up only after Boulware 1970. And 't Hooft's construction of renormalizable theories where the gauge bosons get a mass through the Higgs mechanism came just a year or two later.

Also let's remember that nonrenormalizable theories are not useless or evil, it's just that renormalizability is good because it means the theory can be extrapolated to high energies. As Weinberg mentions, Fermi's original theory of the weak interaction was nonrenormalizable. But it still works within its range of validity.
 
  • #9
Recent reports [http://arxiv.org/abs/1202.1408] [Broken] suggest an overabundance of events around 126 Gev with 3.5 sigma [roughly 99.9%] probability. The probability of this being due to random background noise over a range of energies is estimated at 1.4% [2.2 sigma]. The next LHC run may tell the tale. Particle physicists prefer a 5 sigma confidence level before detection is deemed confirmed.
 
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  • #10
You mean that if I take an abelian gauge theory ( for example,QED ) and add an explicit mass term which breaks gauge invariance, the theory will have no problems with unitarity?
At these , up to the scale where you hit a landau pole?
 
  • #11
Wow. The higgs is almost found. Since the LHC hasn't found any Superpartners and no hidden dimensions nor black holes. I guess the only thing the LHC will ever find is the Higgs before it shuts down in a few years.
 
  • #12
What a load of ill-informed nonsense!

First, there is no such thing as "almost found". Either its found or it's not The experiments have presented their data. Either you are convinced that they have found it, or you are not. The experiments themselves are not convinced.

Second, the idea that because no new physics has been seen with 1% of the total data at half the design energy that no new physics will ever be see is utterly ridiculous.

Finally, "a few years" is more like 20.
 
  • #13
Vanadium 50 said:
What a load of ill-informed nonsense!

First, there is no such thing as "almost found". Either its found or it's not The experiments have presented their data. Either you are convinced that they have found it, or you are not. The experiments themselves are not convinced.

Second, the idea that because no new physics has been seen with 1% of the total data at half the design energy that no new physics will ever be see is utterly ridiculous.

Finally, "a few years" is more like 20.

Oh, so there is still chance the supersymmetric partners that will solve the Hierarchy Problem will be found. Good. I thought they were given up already as not one of them was seen. Thanks for the heads up.
 
  • #14
ofirg said:
You mean that if I take an abelian gauge theory ( for example,QED ) and add an explicit mass term which breaks gauge invariance, the theory will have no problems with unitarity?
At these , up to the scale where you hit a landau pole?
Yes, it's true - just look up unitarity and renormalizability of Proca theory.
 
  • #15
Thanks.
If I understand correctly, massive QED (proca theory) is just a particular gauge of a gauge invariant theory (the stukerberg model), where the scalar field can be removed from the theory.
basically, in order to render massive qed gauge invariant, one only needs to add non physical (gauge redundant) degrees of freedom, in contrary to the non abelian case, where at least one physical degree of freedom is needed (higgs particle).
I this also true for an abelian gauge field which couples chirally to fermions, like hypercharge?
 
  • #16
mitchell porter said:
...For example, you can have a massive abelian gauge boson; it's massive nonabelian gauge bosons which lead to a nonrenormalizable theory, because they contain some extra interactions (and thus extra divergences) not present in the abelian case...

Massive QED is renormalizable? Can you give some reference for that?
 
  • #17
mitchell porter said:
Yes, it's true - just look up unitarity and renormalizability of Proca theory.

I looked it up and it is indeed true. The troublesome kk term droups out in any Feynman diagram due to U(1) gauge invariance.
 
  • #18
Ruslan_Sharipov said:
Alberto Palma's recent paper Arxiv:1202.0217 says in its conclusions part: "The ATLAS collaboration presents first results of the direct search for the SM Higgs boson decaying to [itex]b\bar b[/itex]. No evidence of the Higgs boson was found in a [itex]pp[/itex] collision data sample of [itex]\mathcal L=1.04\ \mathrm f\mathrm b^{-1}[/itex] at [itex]\sqrt{s}=7\ \mathrm T\mathrm e\mathrm V[/itex]. Instead, upper limits on the Higgs boson production cross section of between 10 and 20 times the SM value were determined, in a mass range [itex]110<m_H<130\ \mathrm G\mathrm e\mathrm V[/itex]".

Does it mean that the Higgs boson is already discovered or not yet? What is the exact meaning of these words? What are the most recent news in this area?

It means there were no events in the sample, which had an energy peak at about 90GeV, which were Higgs boson mediated events. It puts a tighter limit on the possible Higgs mass.
 
  • #19
Not yet, we just searched a certain region of the energy, it showed no sign of Higgs, so what physicists can do is try to span the search range.
 
  • #20
Nabeshin said:
The current trend is we think the Higgs is living somewhere at ~126 GeV, see:

http://arxiv.org/abs/1202.1408

But the statistical significance of this is low enough that we shouldn't (and cannot) declare it to be a true detection.

The paper you cite is looking at an (I believe) more difficult decay channel, and is using less data. Plus, it looks like they've only set a bound at ~2sigma.

In your posted article, they speak of the three most sensitive channels:

H → γγ,
H → ZZ(∗) → ℓ+ℓ−ℓ′+ℓ′−
and H → WW(∗) → ℓ+νℓ′−ν

I assume the H is Higgs, γ is a gamma ray, what are ℓ and ℓ′?
 
  • #21
It means an electron or muon. See the first page of the paper that you cite.
 
  • #22
Thanks, makes sense, ℓ for lepton.

Given that they are now interested in the 126GeV range and this list of colliders http://en.wikipedia.org/wiki/List_of_accelerators_in_particle_physics, is there not a number of places that could be searching for the Higgs in addition to the LHC or is there something about the LHC that makes it more likely to be found there?
 
  • #23
This comes from David Kaiser a prof at MIT

At CERN, two independent teams of physicists recently announced that their data were consistent with detection of a Higgs particle, though there remained a 1-in-2,000 chance that the signal came from mundane, non-Higgs processes. So the teams will continue smashing protons together, gathering more data, and sifting for signs of a Higgs.

The original article can be found here

http://www.aljazeera.com/indepth/opinion/2012/01/201211564742186279.html

Does anyone know if what he's saying is true?
 
  • #24
edguy99 said:
Thanks, makes sense, ℓ for lepton.

Given that they are now interested in the 126GeV range and this list of colliders http://en.wikipedia.org/wiki/List_of_accelerators_in_particle_physics, is there not a number of places that could be searching for the Higgs in addition to the LHC or is there something about the LHC that makes it more likely to be found there?

Assume for a moment that there exists a higgs at 126GeV. So, now you should keep in mind that it's not enough to have a collider with center of mass energy of 126GeV to detect such an object! While sure you might produce one, such a production is highly surpressed with respect to other products. The reason we need something so much more powerful is to be able to produce sizeable quantities of the Higgs, and then do these detailed statistical studies. Perhaps the most egregious example is the H-> gamma gamma channel. If you imagine all the junk that's annihilating and decaying in a typical LHC collision, there are an extraordinary amount of photons produced! So to be able to see the 'extra' Higgs photons on top of this background signal requires an appreciable number of Higgs particles to be produced. Since the cross sections for these production processes are strong functions of collision energy, it makes sense to have a collider running at 7 TeV necessary to get good Higgs data (Note: Fermilab is actually able to say something about this because although they ran at a much lower energy, they integrated data over many years, and only just recently [I think] did the LHC surpass them in terms of fb^-1 of data)
 
  • #25
Any progress on finding the Higgs Boson?
 
  • #26
robertjford80 said:
Any progress on finding the Higgs Boson?

?

Have you read ANY of this thread ?
 
  • #27
Yes, of course. Have you?
 
  • #28
Vanadium 50 said:
First, there is no such thing as "almost found". Either its found or it's not
And who decides that? The collaborations? Are 4.99 sigma deviation "not found", and 5.01 "found? There is no sharp line between them, it is a smooth transition with more and more confidence in its existence (if it exists) over time.


Nabeshin said:
(Note: Fermilab is actually able to say something about this because although they ran at a much lower energy, they integrated data over many years, and only just recently [I think] did the LHC surpass them in terms of fb^-1 of data)
~7/fb per experiment (ATLAS and CMS) at LHC, ~11/fb per experiment in ~11 years at the Tevatron. But as the LHC experiments can collect >0.1/fb per day under good conditions, this is just a matter of time.
However, the higher energy is an incredible advantage. The cross-section for the top-quark is larger by a factor of ~20-25. The ratio for the Higgs depends on the mass, it should be similar for a mass of ~125 GeV.
 
  • #29
mfb said:
And who decides that? The collaborations?

Exactly. They will decide based on the evidence whether or not they are confident that they have something.

Note that the collaborations also have additional evidence that is not public - every discovery (or decision that it's not a discovery) I have been involved with was informed by additional information that was not public at the time. For example, the outcome of a parallel analysis.
 
  • #30
That Al Jazeera article is from Jan 18 of this year - it was reporting on some then-recent announcements.

It may be some months before the ATLAS and CMS detector teams decide to report on what they've been seeing. They'll likely report something at this year's ICHEP conference, and almost certainly by the end of this year.

If they go over 5 stdevs, then I think that they'll have enough events to work out decay-mode fractions and the spin of this particle.

If this particle has nonzero spin, then its creation ought to leave a directional imprint on it, an imprint which may be evident in its decay. That imprint will be connected to the beam directions, so one could look for correlations between decay directions and beam directions. Zero spin means zero correlation: isotropic decay. Do I have that right?
 
  • #31
Vanadium 50 said:
Exactly. They will decide based on the evidence whether or not they are confident that they have something.
So what. Would you say that OPERA has found superluminal neutrinos, because they claimed that (in the past)? Did CDF "find" this strange new particle, which was (probably) just a bad Monte Carlo description?
If the collaborations present some 5sigma-result, I'll be highly confident that they saw the Higgs. But it is not a binary decision - the confidence will just be higher than now.


Note that the collaborations also have additional evidence that is not public - every discovery (or decision that it's not a discovery) I have been involved with was informed by additional information that was not public at the time. For example, the outcome of a parallel analysis.
A lot of cross-checks and other stuff, but usually nothing which boosts the significance in a significant way.
 
  • #32
The collaborations' confidence is a necessary but not sufficient condition for discovery.
 

1. What is the Higgs boson?

The Higgs boson is a subatomic particle that is believed to give other particles their mass. It was first theorized in the 1960s by physicist Peter Higgs and was finally discovered in 2012 by the Large Hadron Collider (LHC) at CERN.

2. How was the Higgs boson discovered?

The Higgs boson was discovered by the LHC, which is the world's largest and most powerful particle accelerator. Scientists at CERN used the LHC to accelerate and collide particles at incredibly high speeds, creating conditions similar to those after the Big Bang. The resulting data showed evidence of the Higgs boson's existence.

3. Has the Higgs boson been confirmed?

Yes, the Higgs boson has been confirmed. The discovery was announced in 2012 by the ATLAS and CMS experiments at CERN. Since then, scientists have continued to study the Higgs boson and have confirmed its existence and properties.

4. Why is the discovery of the Higgs boson important?

The discovery of the Higgs boson is important because it confirms the existence of the Higgs field, which is believed to give particles their mass. This discovery helps us better understand the fundamental building blocks of the universe and how they interact with each other.

5. What are the implications of the Higgs boson discovery?

The discovery of the Higgs boson has many implications for physics and our understanding of the universe. It helps to validate the Standard Model of particle physics and opens up new possibilities for further research and discoveries. It also has potential applications in fields such as energy and technology.

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