Largest particle accelerator in existence

In summary, the Large Hadron Collider was activated in 2008 but experienced a malfunction in September. Scientists are optimistic that the Higgs boson will be discovered by the Tevatron before the LHC is operational. If the Higgs is not there, LHC will have a 50-50 chance of finding it.
  • #1
ONON
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I know not far in the past that that largest particle accelerator yet created was set to be activated. Can anyone please give me any information concerning whether or not it was activated and/or the consequences, if any, of what was discovered? Even the name of this contraption and where it is located would be appreciated information.
 
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  • #2
You are propably looking for the Large Hadron Collider, or LHC. See the wikipedia article
http://en.wikipedia.org/wiki/LHC

They activated it on 10 September 2008, but only for testing. No particle collisions at full power took place. An accident, involving a magnet quench and loss of coolant, happened on 19 September, and thus the collider is now under repair. It will be started up again in late September 2009, if there are no additional delays.

Many scientists say that LHC will be able to find the Higgs boson, explaining the mass of particles of the standard model. The facility's startup was also controversial, because some believed the collider could cause major problems like the forming of micro black holes. However, these claims do not have a scientific base, and thus most of the particle physics community finds the collider safe to use.

The discovery of Higgs boson will be a major event, and if it is not detected, the standard model will face some serious problems.
 
  • #3
Nyme said:
The discovery of Higgs boson will be a major event, and if it is not detected, the standard model will face some serious problems.
This is quite naive.
 
  • #4
Many scientists say that LHC will be able to find the Higgs boson

Note that the launch of LHC has already been delayed multiple times. The original launch target was 2005. Then 2007. Then it was "launched" in 2008 just to be shut down for repairs for another year, less than two weeks after launch. It is a very complex system and it has all sorts of kinks that haven't been worked out. Even if it launches, there's no guarantee that it will work smoothly and continuously.

At the same time, the second largest particle accelerator in existence (Tevatron) has been smashing protons and pumping data pretty much 24/7.

In other words, it is getting increasingly likely that existence of Higgs will be confirmed by Tevatron before LHC is even fully operational.

That's assuming that Tevatron is not shut down due to budget cuts.
 
  • #5
shhh …

hamster143 said:
Note that the launch of LHC has already been delayed multiple times.

this is the Large Hamster Collider

it's basically a huge exercise wheel :smile:

it was closed down by animal welfare inspectors … but they don't want us to know that :bugeye:
 
  • #6
LHC (CERN near Geneva), which will be about 8 TeV (trillion electron volts) with two counter-rotating beams of protons, broke on Sept. 19 after several days of commissioning. They are hoping to turn it on again next September. The Fermilab Tevatron (near Chicago) is running now with two counter-rotating beams, one protons, and the other antiprotons, both about 980 GeV (0.98 TeV).
 
  • #7
hamster143 said:
In other words, it is getting increasingly likely that existence of Higgs will be confirmed by Tevatron before LHC is even fully operational.

Doubtful. There are huge regions of parameter space that the Tevatron doesn't cover. If the Higgs is there, you could run the Tevatron for a century and it wouldn't help.
 
  • #8
Vanadium 50 said:
Doubtful. There are huge regions of parameter space that the Tevatron doesn't cover. If the Higgs is there, you could run the Tevatron for a century and it wouldn't help.

If the Higgs is not there at all, you could run both Tevatron and LHC for a century and you won't find it. If it's there and it's a SM Higgs, it's already been excluded by Tevatron around 170 GeV as of last summer. Fermilab's experts say that, even in the worst-case scenario, their chances to discover a SM Higgs are currently 50-50. That is assuming that LHC will go online and work as expected, which we all know it won't.

If it's something less conventional though, then LHC will have its chance.
 
  • #9
hamster143 said:
In other words, it is getting increasingly likely that existence of Higgs will be confirmed by Tevatron before LHC is even fully operational.
Weren't the magnets that failed built by Fermilab ?
 
  • #10
mgb_phys said:
Weren't the magnets that failed built by Fermilab ?

I'm not sure.

First of all, magnets themselves did not fail. What happened was that an electrical circuit between two magnets overloaded and triggered a chain of events that resulted in an explosion that damaged the magnets.

Some magnets were built by Fermilab, some were built by KEK. I don't know who built the offending circuitry. My guess is that it was built on site by CERN personnel.
 
  • #11
mgb_phys said:
Weren't the magnets that failed built by Fermilab ?
Why would that be relevant anyway ?
 
  • #12
humanino said:
Why would that be relevant anyway ?
Only in the sense that Fermilab are the competition to find the Higgs - twirls moustache and laughs manically like a comic book villain.
 
  • #13
humanino said:
Why would that be relevant anyway ?
Only in the sense that Fermilab are the competition to find the Higgs - twirls moustache and laughs manically like a comic book villain.


ps. Yes - the earlier failure when they turned them on and the field strength pulled them out of their mounts was a design problem with the Fermilab magnets, the quench was a bad wiring joint
 
  • #14
mgb_phys said:
Only in the sense that Fermilab are the competition to find the Higgs - twirls moustache and laughs manically like a comic book villain.
Although it is definitely funny, it also a bit simplistic. The HEP remembers who builds magnets. Oxford instrument, for instance, is no longer considered such a reliable provider.
 
  • #15
hamster143 said:
Fermilab's experts say that, even in the worst-case scenario, their chances to discover a SM Higgs are currently 50-50.

Which experts? I am shocked that they would say this.

The Higgs can be anywhere between 114 GeV and about 1000 GeV. With 4 pb-1, the Tevatron has excluded (at 95% CL) just over 1% of this region. According to the http://www-d0.fnal.gov/Run2Physics/HSS_Sum_Aug03.jpg" [Broken], it takes about six times as much data for a discovery than a 95% CL exclusion.

If CDF and D0 are very, very lucky, they will double their data sets. An increase of 50% is a conservative expectation, and reality will probably lie somewhere in between. A factor of six isn't being proposed by anyone, and even that would only open up 1% of the possible search space.

To say that the odds are 50-50 that they will find the Higgs is simply not supported by the information we have now.
 
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  • #16
Just to add one more point, the present Tevatron exclusion limits are better than expectations (i.e. there was a fortunate statistical fluctuation). So this factor of six is probably closer to seven or eight.
 
  • #17
Vanadium 50 said:
Which experts? I am shocked that they would say this.

The Higgs can be anywhere between 114 GeV and about 1000 GeV. With 4 pb-1, the Tevatron has excluded (at 95% CL) just over 1% of this region. According to the http://www-d0.fnal.gov/Run2Physics/HSS_Sum_Aug03.jpg" [Broken], it takes about six times as much data for a discovery than a 95% CL exclusion.

If CDF and D0 are very, very lucky, they will double their data sets. An increase of 50% is a conservative expectation, and reality will probably lie somewhere in between. A factor of six isn't being proposed by anyone, and even that would only open up 1% of the possible search space.

To say that the odds are 50-50 that they will find the Higgs is simply not supported by the information we have now.

Dmitri Denisov of Fermilab was quoted as saying the following at the recent AAAS annual meeting in Chicago:

"...I think we have the next two years to find it, based on the start date Lyn Evans has told us. And by that time we expect to say something very strong. The probability of our discovering the Higgs is very good - 90% if it is in the high mass range. And the chances are even higher - 96% - if its mass is around 170GeV (giga-electron volts). In that case we would be talking about seeing hints of the Higgs by this summer."

By the way, fresh off the presses:

http://www.fnal.gov/pub/presspass/press_releases/Higgs-mass-constraints-20090313.html

They have excluded SM Higgs between 160 and 170 GeV at 95% CL. SM Higgs can't be much heavier than 185 GeV because of electroweak constraints.

So far, CDF and DZero each have analyzed about 3 [tex]fb^{-1}[/tex] of collision data... Each experiment expects to receive a total of about 10 [tex]fb^{-1}[/tex] by the end of 2010, thanks to the superb performance of the Tevatron.

Recall that we need 3 to 5 years of LHC full time at project luminosity to discover Higgs.
 
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  • #18
The failure at the LHC on September 19 was in a splice in the superconducting return cable, not associated with any magnet. They will try to accelerate protons next September. Up until then the Tevatron will still hold the energy record (about 980 GeV per beam).
 
  • #19
hamster143 said:
They have excluded SM Higgs between 160 and 170 GeV at 95% CL. SM Higgs can't be much heavier than 185 GeV because of electroweak constraints.

Of course it can. Those constraints - or rather, their numerical value - assume that there is a desert between the electroweak scale and the GUT scale. In particular, it assumes that nothing stabilizes the Higgs mass against radiative corrections and that the mass remains low purely by accident. That's a model. Maybe a correct model, but it's still a model.

hamster143 said:
Recall that we need 3 to 5 years of LHC full time at project luminosity to discover Higgs.
But that is under the assumption that the Higgs could be anywhere. Ruling out (or making a discovery) in the region accessible to the Tevatron takes less.

As I pointed out, to discover the Higgs, assuming it is lying just past the excluded region (the most favorable place for the Tevatron) will take 6-8 times as much data as they have now: around 25 fb-1. The most optimistic projections are 40% of that.
 
  • #20
By the end of 2010, Tevatron should have enough data to rule out the entire 114-185 GeV range at 95% CL (if Higgs is not there) or to show evidence of Higgs at 3 sigma if it's fairly heavy, say, 150 GeV. If it keeps going beyond the end of 2010, and with some upgrades, 5 sigma discovery is possible.

According to some papers I read, LHC requires 2 [tex]fb^{-1}[/tex] to exclude Higgs from 114 GeV to 1 TeV and 5-10 [tex]fb^{-1}[/tex] for a discovery. (Although the mass range at which a 5 [tex]fb^{-1}[/tex] discovery is possible will probably be excluded by the Tevatron before LHC is even operational.) I can't find any luminosity ramp-up projections on LHC web site, but I recall vaguely that they intend to run at low energies and/or luminosities for the first year or so. How long will it take for LHC to collect 10 [tex]fb^{-1}[/tex] of data, if it's activated as planned in September 2009 and there are no further delays?

How long
 
  • #21
The plot they showed at Moriond shows them a factor of 3 away from a 95% exclusion in the 114-185 GeV. That means they need ~9x the data, or about 36 pb-1.

A 5 sigma discovery takes 6x the data as a 95% confidence level limit. That's 200 pb-1 - twenty times what people are proposing. It's not in the cards - if there was to be a 5 sigma discovery at the end of the run, there would be a 3 sigma effect now. There's not.

It's perhaps worth pointing out that both CDF and D0's silicon detectors were designed to survive about 10 fb-1. At the time, nobody had run any detector anywhere near this long, so there was a huge uncertainty on this number. The point is that it's not obvious the detectors can survive.
 
  • #22
Any news of the larger hadron collider

When's the Large Hadron Collider in Switzerland going to actually start colliding particles together? Weren't they supposed to be done already? I can't get any news of it anywhere, does anyone know anything?
 
  • #23
Have you really searched !? Why did you not begin with CERN's homepage which (to this very day) links directly to Press Release
http://press.web.cern.ch/press/PressReleases/Releases2009/PR02.09E.html [Broken]

(Geneva, 9 February 2009) CERN management today confirmed the restart schedule for the Large Hadron Collider (LHC) resulting from the recommendations from last week’s Chamonix workshop. The new schedule foresees first beams in the LHC at the end of September this year, with collisions following in late October. A short technical stop has also been foreseen over the Christmas period. The LHC will then run through to autumn next year, ensuring that the experiments have adequate data to carry out their first new physics analyses and have results to announce in 2010. The new schedule also permits the possible collisions of lead ions in 2010.
 
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  • #24


T.O.E Dream said:
When's the Large Hadron Collider in Switzerland going to actually start colliding particles together? Weren't they supposed to be done already? I can't get any news of it anywhere, does anyone know anything?

http://lhc.web.cern.ch/lhc/News.htm

they tried, but some magnets was not operating properly.
http://press.web.cern.ch/press/PressReleases/Releases2008/PR09.08E.html [Broken]
 
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  • #25
http://arxiv.org/PS_cache/hep-ex/pdf/0612/0612046v1.pdf

see graph on page 1.

With 10 fb-1, they will exclude the SM Higgs if it's not there or observe it at 3 sigma if it's below 135 GeV.

With 20 fb-1, they will observe SM Higgs at 3 sigma wherever it is, at 5 sigma if it's below 125 GeV.

assume that there is a desert between the electroweak scale and the GUT scale.

That's not what they assume.
 
  • #26
hamster143 said:
That's not what they assume.

Of course it is. That calculation - which I have done, BTW, so this is from first hand experience - assumes that the only particles participating in loops are SM fermions, bosons, and the Higgs. If you add some new particle, it will contribute as well, and move the inferred Higgs mass. In fact, since fermions contribute quadratically and the Higgs only logarithmically, it doesn't take much to move the Higgs mass a lot.
 
  • #27
Vanadium 50 said:
Of course it is. That calculation - which I have done, BTW, so this is from first hand experience - assumes that the only particles participating in loops are SM fermions, bosons, and the Higgs. If you add some new particle, it will contribute as well, and move the inferred Higgs mass. In fact, since fermions contribute quadratically and the Higgs only logarithmically, it doesn't take much to move the Higgs mass a lot.

Your new particle will also have a host of other effects, on many of which (e.g. proton decay or neutron dipole moment) there are stringent experimental limits.

The challenge is to design a particle that moves Higgs to 1 TeV but does not have any other measurable effects.
 
  • #28
hamster143 said:
Your new particle will also have a host of other effects, on many of which (e.g. proton decay or neutron dipole moment) there are stringent experimental limits.

SUSY (above 1 TeV, if you like, so there's no direct detection) can do this. (Not the best example, because there are 5 Higgses in SUSY, not 1, but it shows how a popular model can have this effect.) Extended gauge groups can do this. A fourth generation can do this.

This is not hard.
 
  • #29
Of course we all know that the knights templar and the masons caused the coolant leak leading to the shutdown
 

What is the largest particle accelerator in existence?

The Large Hadron Collider (LHC) at CERN in Geneva, Switzerland is currently the largest particle accelerator in existence.

What is the purpose of the largest particle accelerator?

The LHC is used to accelerate and collide particles at high speeds in order to study the fundamental building blocks of matter and the forces that govern them.

How big is the largest particle accelerator?

The LHC has a circumference of 27 kilometers and is located 100 meters underground.

How does the largest particle accelerator work?

The LHC uses powerful magnets to accelerate particles to nearly the speed of light and then collides them in a controlled environment. Detectors are used to analyze the particles produced from the collisions.

What are the potential benefits of the largest particle accelerator?

Studying particle collisions at high energies can provide insights into the origins of the universe and may lead to advancements in fields such as medicine, technology, and energy production.

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