Science Blog Has Moved
>> Tuesday, May 11, 2010
The UCSD-TV Science Blog now lives in its new location at:
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The UCSD-TV Science Blog now lives in its new location at:
science.myucsd.tv
Please update your bookmarks and subscriptions.
I had titled the last blog pedal to the metal, but as a tyro impressed by the gargantuan machine and counter intuitive contrasts of scales - I really had no idea. Yes, the CMS logged hundreds of thousands of p-p collisions in a day or two. But they were a bit like Saturday afternoon slow pitch, or in deference to my Mentor in this endeavor - backyard bowling practice - as compared to fast yorkers and googlys at the Cricket World Cup.
Man-on-the-scene Matt LeBourgeios on March 30, 2010
As explained to me by our man-on-the-scene Matt LeBourgeois, the last week or so was only preparation for what Vivek calls "The Rediscovery of Physics". Even though my occasional visits to the LHC status page showed 7TeV beams and what looked to me like a lot of luminosity (they were, and there was), there were a lot of not-so-subtle nuances to what was going on. Last week or so was the beam operators; the people responsible for injecting protons into the 27 kilometer race track and providing focused, stable and energetic beams tuning their instrument to perfection.
The line traces the 27 kilometer track of the LHC on the French - Swiss countryside...
As Matt related, the operators maintain that what they provided in that first week or so was not intense enough for "discovery physics"; that is, really compelling huge numbers of protons to collide - but it was exciting enough for our young Ahab (I'll get to that in a later blog) to whet his appetite.
Actually, it was the opportunity CMS needed to tune its instrument, doing among other things something called timing scans, which has to do with setting the triggers on the CMS. This is the realm where Matt works, where he is one of many monitoring all sorts of different parameters and data involved with timing to make sure things are working, or for working out problems when they arise. In his typically gracious manner he calls himself “just a pawn.” I’ll maintain whatever one does on this job is going to mean something pretty darn important one day. Anyway, as Vivek explained, the CMS is like a 100 million pixel camera. The catch, as Matt pointed out, is that each pixel has its own shutter, here in his own words: "the point of the timing scan is to sync the 100 megapixels of the camera. Instead of thinking of having to hit one camera button to take a snap shot, think of it as each 'pixel' has its own button, and these timing scans ensure that we are hitting all 100 million buttons at once." Whew! I can only assume if that doesn't happen, the resulting "picture" lacks focus.
So CMS now has the shutters timed and the beam operators are really putting the pedal to the metal. The latest from Vivek is "...now squeezing the beams like hell - so more rapidfire collisions". What? Vivek explained that the beams that collided on March 30 were something like the diameter of a hair, now the operators are tuning the beams to be something much thinner (?!!)- with the same number of protons in the beams. They're focusing and concentrating the beams. Why? Same number, smaller space = greater density = greater luminosity. Vivek has a vivid description of those less focused March 30th beams in this video clip.
Another way to put it is like shooting two shotguns at each other - you get two bunches of shot, each with 10 to the 11th pellets (that's like, oh, a hundred billion pellets in each), flying towards each other in the hope that some of the pellets hit directly head-on with all their momentum going into their mutual deconstruction. The more concentrated the shot pattern, the better the odds of collisions. So when the operators can provide focused, stable beams, then people like Vivek and Matt and their colleagues can really do their work - which is PHYSICS; and the operators can post messages like "enjoy the collisions" and "physics beams" on the LHC status page here. Now I've simplified, and probably to the horror of physicists out there, over-simplified this. Be certain, there are a lot of precise and very specific protocols involving terms like beta-star and picobarns that indicate the level of performance and quantity of data the physicists are getting - very strict parameters that are adhered to, because remember-they're working with things we can't see, have never seen before, and whose existence we can only infer, albeit very precisely and with great certainty, but only through the evidence they leave behind.
So what is that evidence? Well in the energy range - or mass - (remember it ALL boils down to this - E=mc2) in which the LHC will be looking for the next year or so, the signature of a Higgs boson of about the mass of an entire gold atom (which is about 185 GeV!), will be the remains of two W bosons. And that - which Matt and Vivek and a few thousand others will be looking for - will be events that show specific combinations of electrons, muons, or electrons and muons AND their corresponding neutrino counterparts, which show up only as a precise amount of missing energy - something called Missing Transverse Energy. If the event shows all three of those parameters to an exceedingly high degree of certainty, then it will get some interest, and Vivek, Matt and a world of physicists will pore over it. The catch is, one event won't be telling. They need several such events, enough to satisfy something called 5 sigma criterion - I know you all know what that indicates, sorry I'm playing catch up, but for those like me, it is a term describing a statistical certainty to a level of less than one fault in a billion. In other words, there is only less than a 1-in-a-billion chance that they're wrong. So you need a lot of incontrovertible events, and to get several such events...you need thousands, millions and ok I'll hyperbolize, (but I have a feeling it isn't really hyperbole) - probably billions of p-p collisions to get those events. Just to add another twist, as Matt told me the other day, W boson production, without the creation of a Higgs first is almost a hundred times more likely to occur. So there will be a lot of W bosons that show up WITHOUT evidence for Higgs....hence, collisions, collisions, collisions, "squeeze the hell" out of those beams. And then there are the usual gremlins encountered with complex systems. Vivek recently showed me how one such event looked interesting, but one of the parameters was due to an instrumental glitch - so, "close but no cigar" and into the trash with that one....so, collisions, collisions, collisions.
In the meantime, as the operators keep perfecting their craft, "squeezing the hell" out of the beams, with the p-p events occurring at an ever accelerating rate, Vivek and company are happy to do what Vivek describes as "Rediscovering Physics". It isn't just an idle exercise or coincidence of smashing protons. As of the Ides of April Vivek explained that the LHC has “discovered” every major particle revealed in the 20th century, up to about 1983, when Carlo Rubbia discovered the the W and Z bosons. Or that is - it has rediscovered them, and this is important why?
This is a new instrument, a new machine, and as Vivek explained, if you don't see what you already know about with this machine, then you may have a problem with your instrument, and basically, you can't trust the results....So now, working at heretofore unattained energy the LHC has tallied a gamut of fundamental particles, starting with the pi mesons of 1947. Their discovery bolstered the existence of Up and Down quarks. Oh, and the LHC attained this in the first 15 minutes of operation at 7TeV. Then it was the Strange (50's) and Charm quarks of the 70's and on and on. As of this writing they're still in the hunt for the last few particles - variations of the Z boson, a hunt which might end at any moment the way they're smashing zillions of protons (my hyperbole). Even for a naive eye the data is totally convincing, you'll be able see it soon when it is published and when you do, I think you'll agree it's waaaay 5 sigma. And that's a good thing. The LHC is seeing what it is supposed to be seeing - so when new things show up - those electron-neutrino (elnu), muon-neutrino (munu), MTE (Missing Transverse Energy) triptychs of data - Vivek and friends will know it isn't a phantom - but instead, perhaps, the sign of the holy grail, the great white whale, or as it has been called - the god particle.....Bonne Chasse mes amis!
First of all, we are grateful for Matt LeBourgeois who recorded all this unique and singular footage, more of which you will see in UCSDTV's chronicle of his and Vivek Sharma's experiences during the first year of the Higgs search. Matt got it good, where the rest of the media can't....
Just moments after the first 7TeV proton collision ever recorded occurs in the Compact Muon Solenoid detector - for which Vivek directs the Higgs search, Matt caught Vivek's comments as the first record of the event appeared.
Now that the big press event has subsided, and the terms LHC, CERN and Geneva fade as our attentions are prodded to such things as Ricky Martin's personal life, the economic recovery and improving relations with China (unless you're Google)-all issues with varying degrees of import; the real work for thousands of scientists begins. As Vivek so prosaically put just moments after viewing the record of the very first 7TeV proton collisions ever created "...the events are beautiful, the detector is working like a dream....you know, it's taken twenty, twenty-five years to build and this is what it is for, finally, the baby is delivered, now it has to grow...".
And they are quickly exhorting their baby to take its steps and grow. Shortly after the champagne corks were gathered up and the press hit "send" to file their media, Vivek's cohorts in this huge endeavor slowly, or not so slowly, started putting the pedal to the metal. Still basking in the excitement, Vivek hints at what the next steps for their baby would be:
And as later reported by Vivek, on the very same day the CMS recorded more than 500,000 p-p (proton-proton) collisions in just a few hours. And on Wednesday and Thursday of this auspicious week, they accumulated more than four million collisions at 7TeV, with plans to increase the collision rate by orders of magnitude in the next weeks. Baby steps indeed....
So just what are we looking at in this video? Vivek explains in response to a presumably UK journalist:
Their baby - our baby - has started the marathon, and we'll be pacing alongside with Vivek and Matt. Keep checking back, and don't forget to use your iPhones and browsers to take a peek at LHC status, and in a way, take part, however vicariously, as we venture on into this new epoch of understanding that started just a few days ago.
The Dawn of a New Era
These are the first things I looked at when I awoke this morning.
First release images of 7TeV collisions in the CMS detector, March 30,2010
Apologies folks, but I can't resist the tendency to the poetic. It's an irresistible force. Yes, they look like hieroglyphs, or something truly alien, or perhaps just colorful scribbles, and it is certain the naysayers and luddites will proffer a plethora of snarky remarks. And in all honesty, I could tell you very little about what the traces show - but for one thing.
These are a record of something utterly new, heretofore unknown, and never before seen in the entire history of what we collectively call ourselves - the human race.
We are truly at the dawn of a new era. Not just for physics, but perhaps for everything we understand.
How can one make such a bold, perhaps foolhardy statement?
Keep in mind a passel of physicists with tons of graphite in a field house at the University of Chicago some 60-odd years ago. Or even earlier in the 1850's, when an English tinkerer moved a magnet over some coiled wire. Those are just a couple of things that changed the world forever - and made our world what it is.
Now we - humanity - are looking deep into the pieces of the bits of shards of atoms and beyond into who-knows-where. Just like Fermi at Pile 1 and Faraday in his study, and all the rest who knew not what they were looking at, except that what they were looking at was new.
So the statement is not so bold, or foolhardy. It is in fact, certainty.
UCSD-TV will be chronicling the advent of this journey as we provide a unique perspective through the exploits of UCSD Professor of Physics Vivek Sharma and his graduate student, Matt LeBourgeois. Here is a preview of material we recorded just days before the start of the journey.
More will be coming as the collisions continue and the journey proceeds.
You can follow along with near real-time views of LHC and CMS status, as well as see collision images here. You can even put it on your iPhone....like, as my daughter is apt to remind me, the "inner" (or some might say not-so-inner) nerd in me did...
Another interesting blog to glimpse a different perspective of the journey is here, provided by CMS e-commentators Darin Acosta, Dave Barney and Lindsey Gray. A lot of it may as well be runes or Sanskrit to most of us - we'll work on translating as much of it as we can as this project evolves, but I'm fascinated by it because it is a unique chronicle of what is a wholly new, and certain to be, fantastic journey.
March 29, 2010. Within a few hours, while you sleep soundly, the most energetic particle collisions ever produced by humans will occur half-way around the world. Scheduled for the morning of March 30,2010, Geneva time, two beams of protons each at an energy of 3.5 trillion electron volts will be directed to slam head on into each other at about 99.99999999 percent of the speed of light. And Science on UCSDTV is there, following along with UCSD Professor of Physics Vivek Sharma and one of his graduate students, Matt LeBourgeois. While Vivek is half-way around the world at CERN, he is only one of 24 UCSD physicists, including Frank Weurthwein, who are working on the project.
Vivek is the Director of Higgs Research for the CMS detector on the LHC, the Large Hadron Collider. That means he coordinates a huge international team of the world's top physicists, researchers and technicians to conduct a search for the only fundamental particle in the standard model of particle physics that has not yet been detected. It is often referred to as 'the god particle'. Why? It is postulated that this 'god particle' - less poetically the Higgs Boson, is the particle that confers the property of mass to everything - from fundamental particles like quarks on up to you and me, and, well, everything. It also has all sorts of other implications we'll get into as this project evolves.
So, what is the CMS you ask? Steel yourself for an anagram-a-palooza rivaled only by the likes of NASA. The CMS is The Compact Muon Solenoid. That will be explained in later posts - but essentially it is a 100 million channel "camera" that can output "pictures" or record events on the order of fractions of microseconds, a bit faster than your digital snippy-snap, as innumerable fundamental particles spray off of innumerable proton collisions occurring each fraction of a fraction of a second.
Here's a sneak preview of some early footage for the project we recorded using remote connectivity with VoIP, iPhones, laptops and home video cameras.
You'll never see the CMS Center this quiet after March 30,2010
And even more cool, you can follow the status of the CMS detector, the LHC, and see photos of the CMS, here. And when they have the data - images of the most energetic particle collisions ever created.
Here's a little bit of information on what you might see on one of the pages. I'm still working on getting it figured out, and it's kind of fun to explore. We'll take it slowly so we don't get paralyzed by alien information overload. On the LHC status page you'll sometimes see three values across the top: Energy, I(B1) in blue and I(B2) in red. Energy is how energetic each beam is. And I is intensity of each beam. So when you see 3500GeV for energy, that's 3.5 Trillion Electron Volts - the most energetic beams ever created. When the two 3.5TeV beams collide, that's 7TeV put into that collision, enough to blast protons and hopefully top quarks apart into their many varied constituent fundamental particles - and as is hoped and envisioned, we'll see the telltale signature of the Higgs Boson.
Now don't despair if all this rarefied physics is confusing. It is, but only because it's new. Hey, I'm right along with you on this. If you don't know what the words LHC, Higgs or CERN mean, stay with UCSD Science blog and we'll be working to get you up to speed on what could, and should, prove to be a watershed in our understanding of well, in a way....everything. Pretty soon this will all be as familiar as air and water.