200GeV Collisions at RHIC 47
PHENIX Experiment writes: "Brookhaven Labs has produced for the first time, collisions of gold nuclei at a center of mass energy of 200GeV/nucleon. This is a new energy regime for the high energy nuclear physics relativistic heavy ion program which is now getting underway. We have put together a bunch of nice photos of event displays for some nice central collisions, the collisions where the two nuclei hit head on. Over the next 6 months or so, we are looking to collect on the order of a petabyte of data which will then be analyzed using our VA Linux farm operated by the RHIC Computing Facility."
Re:Wow. 200GeV (Score:2)
This sort of accelerator explores a different physical regime from something thje LHC or the Tevatron, which use single higher-energy particles. It
Re:IANANP.....by I am (Score:2)
By finding these sub-particles we can figure out how the particles in the "particle zoo" behave, why energy and matter appear as they do, and how the universe formed etc.
Re:Wow. 200GeV (Score:1)
According to Lexx... (Score:1)
Re:They're looking for Quagma *grin* (Score:2)
Re:Quark/Gluon plasma (Score:1)
Re:In real life terms please (Score:2)
you're looking for real-life benefits from particle physics?
As someone who has worked in both particle physics and medicine I can point out:
*) development of accelerators for cancer radiotherapy, used routinely in hospitals every day
*) advanced dedicated accelerators for novel cancer therapy, like pion therapy and boron neutron capture therapy
*) synchrotron light sources, used for biomedical and semiconductor materials research
*) detectors developed for Positron Emission Tomography scanners
*) development of high field superconducting magnets, as used both in particle detectors and MRI scanners
I think that's a good few examples!
They're looking for Quagma *grin* (Score:1)
Strangelet Disaster (Score:1)
Re:Large detective work ahead (Score:2)
In a word, no. These energies were reached a long time ago, but the lack of a Higgs is not surprising. Remember that the Higgs is never produced alone, and that other particles produced need energy too. You need a center of mass energy on the order of a few TeV before you look for the Higgs.
and.. (Score:1)
Re:Equals means equals (Score:2)
Well, Yeah, But What About... (Score:1)
That was a lame joke. Oh well.
Re:Large detective work ahead (Score:1)
1. Be precise. I guess when you say SUSY you mean MSSM (Minimal Supersymmetric StandardModell).
2. There are enough free parameters in other SUSY scenarios to tune the Higgs to whatever mass you like.Upper limits on the Higgs mass are derived from cosmology, and are not directly computable from underlying models on particle level
3. They might have 200GeV sqrt(s) but that does not mean they have 200GeV for single Higgs production. There is actually not very much energy left to produce a Higgs, when see all the dirt that is produced in a heavy Ion collision.
Re:Blackholes from particle collisions (Score:2)
Re:Wow. 200GeV (Score:3)
IANANP..... (Score:1)
I am not a nuclear physicist....could someone who is more qualified explain the importance of this? Does it mean we can get more energy than previous materials?
Or are we gonna see all of fort knox melted down so mister Dubya Bu$h can blow up china and make a nuclear winter that lasts even longer than the 60's estimates?
Just curious :)
In real life terms please (Score:1)
Equals means equals (Score:1)
Point in fact - Mercury's orbit. The orbit of Mercury had significant perturbations that caused concern at the turn of the century. Some astronomers postulated a small planet inside Mercury's orbit, called Vulcan (a very logical name), that was the source of the extra gravity causing the problems.
However, Vulcan was never discovered. With Einstein, came the realization that the sun's gravitational field, which is a huge amount of energy, corresponds to a smaller but still huge amount of mass, which has its own gravitational field. So Mercury is ok after all because what you said is true.
So, (getting back on topic), that 200 Ge/nucleon is mass, just in the form of photons, so it has gravity. A *very* small amount of gravity. I don't feel like doing the math, but the mass/volume ratio that determines black hole-ness probably has plenty of volume to spare.
So, no dice for now. And even if it did happen, not really a worry. As long as one is far enough away to not worry about tidal effects, it doesn't matter how concentrated that mass is.
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Re:In real life terms please (Score:1)
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Re:200 GeVs ?!? (Score:2)
So are the gold atoms OK? (Score:1)
Sad that gold has turned away from being the world's foremost item of currency into a ping-pong ball for physics experiments.
Let's see, at US$270.30/troy ounce (London PM fix), works out to US$8.69/gram.
So how many gold atoms were subjected to this horribly painful experiment? I don't know, the articles didn't say. But then the Ministry of Forests doesn't release numbers of spotted owls [mybc.com] either. But I digress...
There are 6.02*10^23 gold atoms in a gram (it is monovalent usually in an isometric crystal as a native mineral). Let us assume that two hundred innocent gold atoms were subjected to this "experiment". That works out to 3.32*10^-22 grams of gold! (Or in other numbers, that is 3.32*10^-28 TONNES!). At the present gold price, that works out to US$0.0289*10^-19 !!! Wasted, I say!
Are all you US taxpayers as horrified at the expenditure of your tax dollars on this experiment? Here is what you do:
Fire up your web browser and point it to the white house web site [whitehouse.gov]
send them a message expressing your outrage. I suggest the following: /default.ida?NNNNNNNNNNNNNNNNNNNNNN
GET
That should get our message out there. Save the Gold!
-AD
Now I'm Mad... (Score:1)
On to a more serious note, though. According to some scientists, this was supposed to be capable of yielding either a singularity (black-hole) or strangelets. Of the two, strangelets would be by far the worst. Some very well renowned physicists came back and said that the chance "was extremely small"
One thing to remember (I think Einstein said it, actually): in Quantum mechanics, if it can happen, it will.
I can't wait! I'll be playing Tool's AEnima as the stranglets obliterate normal matter.
"Mom, please flush it all away..."
Re:Big Science == Dangerous Science? (Score:1)
When RHIC was being designed a lot of possible disaster scenarios came up. A very serious study was done by some rather well-respected physicists, with the results in a paper that can be found here [lanl.gov]. They found that the possibility of a black hole forming was very small, and that all of the other disaster scenarios were also very unlikely.
Re:Blackholes from particle collisions (Score:2)
In relativity, mass and energy are equivalent. We know that E^2 = m^2*c^4 + p^2*c^2 (E=energy, p=momentum, m=mass, c=light speed) where E=MC^2 is the case for a massive particle at rest and E=PC for a massless particle such has a photon, since m=0. As long as you have enough energy in a small enough volume, a black hole can form. This works because, as stated before, mass and energy are equivalent in relativity. Photons are massless but have energy, so in theory one could create a black hole just by having enough light in one place! It's awfully hard to do in practice, though, as the energy density needed is very, very high.
Interestingly enough, one can also generate a black hole by having constructive interference between very strong gravity waves. I saw a video from a simulation that showed this happening at a relativity conference I was at (I'm an astrophysics grad student) and it was very cool. I can't seem to find the link and google is on the fritz, but I believe that it was a simulation done by the Virgo Consortium (a bunch of European universities).
Quark/Gluon plasma (Score:4)
One of the main reasons that RHIC was developed was to study the quark-gluon plasma. Though there are more energetic acclerators (Fermilab's Tevatron, for example), RHIC is unique because it collides gold nuclei together instead of single atoms or leptons. Even so, most of a gold nucleus is empty space, so when they collide, the nuclei basically pass through each other, but at such a high energy that the bonds that hold the quarks together are temporarily broken, creating a very hot, dense quark-gluon plasma. (BTW, gluons are the carriers of the 'strong' force and hold quarks together to make hadrons such as protons and neutrons). This allows physicists to study the properties of very hot, dense matter, such as the stuff that existed shortly after the big bang, before the era where protons and neutrons were formed. A paper describing the potential physics of it can be found here [lanl.gov].
Re:Blackholes from particle collisions (Score:1)
I don't know if this would work, but I think the answer would depend on wheather or not energy has gravity. I'm assuming that gravity causes black holes, which could be wrong. If energy does have gravity, it would be 1/c^2 times the gravity of matter, maybe? So in the ammounts of energy we can deal with, the gravity would probably be unmeasurable, so this would all depend on the math.
Disclaimer: Yes, I am still talking out of my ass.
Since Google isn't going to help with this stuff, methinks an actual scientist is required. Someone qualified please post! This is really interesting. Somebody mod Procrasti up too. This is a damn good question.
The Hardware (Score:3)
No, I remember really. (Score:2)
Not quite like pool, but nice english (Score:3)
The gold ions don't collide as such and shatter. IANAHEPPOAFYOLE (I am not a high energy plasma physicist or 15 year old leagal expert), but because they're traveling at relativistic speeds they pancake and pass through each other inelastically imparting some of their lost energy to the vacuum behind them. The vacuum, being unstable with this extra energy spots forth a soup of primordial particles. Particles, who's composition depends on its temperature, which in turn comes from the enegry imparted to the vacuum in the collision. One interesting particle to look at is J-psi. They could simply graph detections of J-psi artifacts vs temperature or energy density (variable the researchers control). It should look just like any phase transition diagram, such as one might do for ice to water. At a certain critical temperature J-psi should essentially 'melt' and then we would know our quark gluon soup is done. And if my hamerster is right, that should be at about 2 trillion degrees K. Careful, the soup's hot.
In a way, what is being done is looking, in extreamly fine detail, at what came before the cosmic background by something like 300,000 thousand years when our universe was about the size of the solar system.
I think someone published a paper that a device like this might impart enough energy to the local vacuum, that it might settle back down to a lower energy state and trigger a big bang giving birth to a new universe. (Now that would be the weapon of an evil genious worthy of James Bond.) Supposedly something like 5,000 similar lead - lead collisions take place every year in the universe, so it's probably pretty unlikely. But it would be pretty funny if they had to state man wouldn't destroy the universe from Long Island for the EPA. Of course it'd probably be even funnier if they were wrong.
You've got to love the dry humor.... (Score:3)
Don't you get the impression they resented having to write this?
Re:Big Science == Dangerous Science? (Score:1)
I don't know about you, but I'm going to enjoy the happy fun superslide ride given it's the last thing to enjoy before the sewage pool plunge.
Re:In real life terms please (Score:1)
Re:Big Science == Dangerous Science? (Score:2)
The argument against was that far higher energy collisions happen constantly in the high atmospher, on the moon, other planets, for billions of years and they haven't fallen prey to such a situation.
The other theory, that it would create a black hole, never held much water because it would radiate away its mass instantly, far more rapidly than any nearby particles falling into it could replenish it. It requires being at the core of a massive gravity well to keep feeding it to overcome this (presumably, and that assumes black holes actually exist.) In one story I read, it was estimated a black hole would have to be about the size of a marble before it could feed itself fast enough on (or in) a planet (at which point, you'd only have a few seconds left to live anyway. You'd probably die a fraction of a second before being pulled in because your body was torn apart, atom-by-atom, by the tidal force difference in the gravity between your feet and your head.)
Re:and.. (Score:1)
[Name that obscure reference for one karma point.]
Large detective work ahead (Score:3)
But then again, they have those Linux'es to handle that, so i guess they'll manage. One doesn't start something like this unless you are quite sure you'll learn something.
Yours Yazeran
Plan: To go to Mars one day with a hammer.
Re:and.. (Score:2)
Dizzy: What good are all these things? Faraday: One day, Sir, you may tax them.
Alternative: Faraday: What use is a baby?
Re:Oh yeah, Then... (Score:1)
Re:In real life terms please (Score:1)
every new generation of these beasts creates (and solves) incredibly hard scientific and engineering problems.
it has been said that building of the proton-proton accelerator in cern is the technology equivalent of 10 space shuttle missions.
accelerator technology overcomes the following engineering problems (that I know of): hard vacuum exposure (over years) of both superconducting magnets and very sensitive detectors in incredible amounts (kilometers), very high radiation exposure of above devices and materials (one of the problems fusion tech still has to face, BTW) and (for CS people:) filtering and clustering enourmous amounts of data.
plus, there's the computer simulations of above structures , reliability and perfomance analysis etc., etc.
in real-life terms: such incredible effort by at least tens of thousands of very smart people trying to overcome new problems must bring a side benefits (look e.g. at space program.)
Re:Large detective work ahead (Score:1)
how do they feel about relocation? (Score:1)
Come on, it's all for the sake of scientific advancement.
Blackholes from particle collisions (Score:1)
We all know that a blackhole forms when you have so much mass in one place in space that even light can't escape its gravitational effects and a singularity forms.
We also know, from Einstein that mass and energy are interchangalbe by the formula E=mc^2.
Does this mean that in order to form a black hole all you need to do is put enough energy into a small enough volume? If so, how would this work, and if not, why not?
Thanks
Quark would be happy... (Score:2)
200 GeVs ?!? (Score:2)
Re:In real life terms please (Score:1)
They may find nothing at all. They may find something totally revolutionary. But until they find it, they won't know. They may not even recognize what they've found at first.
Re:In real life terms please (Score:1)
Re:Large detective work ahead (Score:1)