Quark-Gluon Plasma Discovery - Brookhaven National Lab

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In summary, scientists at Brookhaven National Lab were able to generate 4 trillion degrees Celsius when they collided gold ions. However, at CERN they have a particle accelerator at 17 miles in circumference, much larger than the one at Brookhaven National Lab. So how come they didn't report similar news earlier, or maybe with the news of the 3.5 TeV particle collision lately? Quark-gluon plasma requires heavy ions; with nucleons not enough quarks are involved. Quark-gluon plasma requires heavy ions; with nucleons not enough quarks are involved. Therefore, the scientists at Brookhaven National Lab were only able to generate a temperature approximation of the perfect liquid. The scientists at C
  • #1
ionowattodo
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Lately, I've heard that the scientists at Brookhaven National Lab were able to create a collision between gold ions that generated 4 trillion degrees Celsius. They said that this amount of energy in the collision was more than enough, according to their calculations, to melt the nucleons into a plasma of quarks and gluons. Link: http://www.bnl.gov/rhic/news2/news.asp?a=1074&t=pr
However, at CERN, they have a particle accelerator at 17 miles in circumference, much larger than the one at Brookhaven National Lab (2.4 miles in circumference.) So how come they didn't report similar news earlier, or maybe with the news of the 3.5 TeV particle collision lately?

I'm fairly new at this subcategory of physics, so a discussion about this new discovery could hopefully benefit my knowledge on such science. Any ideas on this?
 
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  • #2
Quark-gluon plasma requires heavy ions; with nucleons not enough quarks are involved.
 
  • #3
tom.stoer said:
Quark-gluon plasma requires heavy ions; with nucleons not enough quarks are involved.

I thought scientists at CERN fired lead ions? If lead is heavier than gold chemically, wouldn't it create a much greater temperature due to the collision of more quarks?
 
  • #4
ionowattodo said:
I thought scientists at CERN fired lead ions?

Not in the LHC yet.
 
  • #5
The LHC right now concentrates on calibration and checking standard results. It is best done with cleaner events. Proton and heavy ions are both parts of the ultimate physics program.
 
  • #6
I see.

Did the scientists at Brookhaven National Lab confirm the temperature of the collision event? Correct me if I'm wrong, but I think that they measured the wavelengths of the released particles and calculated the temperature from there.
 
  • #7
yes, something like that;

it's not straightforward to define a temperature; temperature means that we have thermodynamical equilibrium,whereas the qg-plasma state has of course a very short lifetime; so this is "on the edge"
 
  • #8
If QGP has a very short lifetime, why is it so significant to scientists? I've heard that some people think it leads to the Big Bang theory, but if this collision event really does recreate something similar to the Big Bang, how come it didn't expand tremendously into an entirely new universe? Also, how can it be possible to accelerate particles (maybe even nucleons at the very least) without the aid of man-made machines?
 
  • #9
As for every high-energy experiment with the LHC we come a bit closer to the Big Bang, but not really close!

The Tevatron has ~ 1TeV c.o.m. energy, the LHC will have 14TeV (both in hadron collisions, of course much higher for heavy ions). The Planck energy is ~1016 TeV. In addition the Big Bang is different as spacetime emerged from it, therefore the high energy density was realized in the hole (tiny) universe with Planck length ~ 10-35m. Today the tiny volume with QGP is surrounded by a gigantic (nearly empty) spacetime into which the plasma can expand, whereas after the Big bang the plasma could only expand by "creating new spacetime".
 
  • #10
tom.stoer said:
As for every high-energy experiment with the LHC we come a bit closer to the Big Bang, but not really close!

If the experiments at the LHC and Brookhaven National Lab weren't even approaching the energies needed to replicate the Big Bang, what's the point of even initiating the experiment? Since these experiments deal with quantum particles, the scientists have to reach a specific amount of energy input on the particles in order to obtain a result similar to the Big Bang.
 
  • #11
The answer is simple: the scientists do not want to study the big bang as they are aware of the fact that they are still some orders of magnitude away from it. Instead they want to study the standard model, especially the Higgs particle, perhaps physics beyond the standard model like SUSY, QGP etc.
 
  • #12
ionowattodo,

I saw your post a few days ago, you may find these posts of interest, in jal's "perfect symmetery" thread. This has to do with BNL's findings concerning quark-gluon-plasma. See what you think. Starting with https://www.physicsforums.com/showpost.php?p=2582244&postcount=89", consisting in part of quark-gluon-plasma. Plenty to think about, enjoy and welcome to PF.

Rhody...

P.S. I just read your response in post #6. See jal's response in https://www.physicsforums.com/showpost.php?p=2588442&postcount=92" about half way down the page. A good explanation of how the temperature was calculated:
I realize that when writing for the the news media that things have got to be “dumbed down” to make it understandable.
The repeating of “measuring the temperature of the quark-gluon plasma as 4 trillion degrees Celsius,” should be clarified.
The temperature of the “ball/bubble of plasma/liquid/fire” is not being measured.

What is being measured are the temperatures of the jets NOT THE TEMPERATURE OF THE PERFECT LIQUID.

Therefore, the presumption and assumption that the perfect liquid is at those “temperatures” needs to be taken with a grain of salt.
 
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FAQ: Quark-Gluon Plasma Discovery - Brookhaven National Lab

What is Quark-Gluon Plasma?

Quark-Gluon Plasma (QGP) is a state of matter that is believed to have existed in the early universe, just after the Big Bang. It is a hot and dense mixture of subatomic particles called quarks and gluons, which are the building blocks of protons and neutrons.

How is Quark-Gluon Plasma created?

Quark-Gluon Plasma is created by colliding heavy nuclei, such as gold or lead, at very high speeds. This causes extreme temperatures and densities, causing the nuclei to break apart into their individual quarks and gluons.

Why is the discovery of Quark-Gluon Plasma important?

The discovery of Quark-Gluon Plasma helps scientists to better understand the fundamental forces and particles that make up our universe. It also provides insights into the conditions of the early universe and the formation of matter.

What is the role of Brookhaven National Lab in the discovery of Quark-Gluon Plasma?

Brookhaven National Lab is home to the Relativistic Heavy Ion Collider (RHIC), which is one of the world's largest and most powerful particle colliders. Scientists at Brookhaven have used the RHIC to conduct experiments and make important discoveries about Quark-Gluon Plasma.

How does the study of Quark-Gluon Plasma contribute to advancements in technology?

The study of Quark-Gluon Plasma has led to advancements in technology, such as the development of new imaging techniques and computer simulations, which can be used to study other complex systems. It also has practical applications in fields such as nuclear energy and medicine.

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