GeV Acceleration In 3 Centimeters

ZonkerWilliam writes, "Here is a very interesting article, for the scientific community at least, on an advancement in laser wakefield particle accelerators. Being able to accelerate electrons to 1 Gev in the space of 3.3 cm calls up visions of portable devices that can be used anywhere: think of portable cancer therapies, if they can do the same for positrons, portable PET scans, possible use in compact fusion devices, capturing the dearly departed, etc. The uses are mind boggling." From the article: "By comparison, SLAC, the Stanford Linear Accelerator Center, boosts electrons to 50 GeV over a distance of two miles... The Berkeley Lab group and their Oxford collaborators... achieve a 50th of SLAC's beam energy in just one-100,000th of SLAC's length." I doubt that this tech will fit on a table top anytime soon. The article quotes the Berkeley researcher: "We believe we can [get to 10 GB] with an accelerator less than a meter long — although we'll probably need 30 meters' worth of laser path."

What is this "blaster" you speak of?

[ChePibe]

I believe Han Solo's only notable piece of equipment is a small bouquet of daisies, one of which he gives to Guido in the super-hyper-ultra-master-remix of Star Wars Episode -12.

Why on earth would Han want to "blast" anything, as is? He's a perfectly legitimate businessman, brought into hard times by a pair of misfits who attack people with Mag Lites... or at least that's the latest Lucas version.

idiot editors

[1u3hr]

"We believe we can [get to 10 GB]...

GB = gigabyte
GeV = giga electron Volts

Also, TFA links to an illustrated version of the story.

Re:Imagine

[AKAImBatman]

We're talking about electron volts. You see, electricity is not the electrons themselves, but rather a wave of energy passing from one electron to the next as they collide with each other. (A bit simplified, but hey.)

You know those desk decorations that have about 5 metal ball suspended from wires? If you lift one and let go, gravity imparts energy on one of those balls. When it hits the next ball, it transfers energy to the other ball, which in turn hits the next ball, transfers its energy, so on and so forth. When the last ball has nothing more to hit, it swings out from the kinetic energy imparted on it. This is pretty much how electricity works.

An electron Volt is a method of measuring the kinetic energy for individual particles. It translates directly to the voltage/joules calculations we all know and love, except that it only involves one particle instead of a wire full of them. Most commonly, this term is used in particle physics where the energy of a single particle matters.

What has been built here is a micro particle-accelerator capable of imparting massive velocities on individual electrons. This is useful for things like advanced medical scanners which bombard a target with a small number of high energy particles in order to get 3D image of the object. With a small enough particle accelerator, we could begin building devices like the medical tricorders you see in Star Trek. That's never been possible before.

Capturing the Dearly Departed

[A+Brand+of+Fire]

When using a portable particle accelerator, always remember this important safety tip:

Egon: There's something very important I forgot to tell you.

Venkman: What?

Egon: Don't cross the streams.

Venkman: Why?

Egon: It would be bad.

Venkman: I'm fuzzy on the whole good/bad thing; what do you mean, bad?

Egon: Try to imagine all life as you know it stopping instantaneously and every molecule in your body exploding at the speed of light.

Ray: Total protonic reversal.

Venkman: Right. That's bad? Okay. All right. Important safety tip. Thanks, Egon.

The actual speed... 0.999999869 c

[Ruberik]

For anyone who's interested, the actual velocity of the electrons is about 0.999999869 times the speed of light -- which is why talking about GeV is more instructive than talking about how fast the particle goes. The math follows, if you're interested.

1GeV = energy = gamma * m * c^2 (gamma = 1/sqrt(1-v^2/c^2))
1 GeV / c^2 / m = gamma
1957 = gamma = 1/sqrt(1-v^2/c^2)
v/c = 0.999999869 ... or you can type sqrt(1-1/(1GeV / electron mass / c^2)^2) into Google Calculator.

Interesting fact: we usually hear about E = mc^2. That's the direct matter->energy conversion when the matter is at rest: if the matter is moving, we add on a factor of "gamma" -- which, at small velocities, is about 1 + 1/2 * v^2/c^2 (giving E = mc^2 + 1/2 mv^2, or rest mass + classical kinetic energy!)

Re:Forgive me for my lack of knowledge

[deglr6328]

No, the laser light is turned INTO the energy of the electron beam. It is not infinitely reusable.

That said, I don't see very many posts yet which address the central importance of this news. So let me do that now. THIS IS HUGE HUGE HUGE NEWS. I would be shocked if the LOASIS group weren't on stage with the king of Sweden in a decade or so. Seriously, that's how big this is. No one expected things to happen this fast in wakefield acceleration. No one. Just two years ago I posted a story here about the latest achievement of the same wakefield acceleration research group. They were then at 80 MeV electron energies over millimeters of acceleration distance using a 10 terawatt laser pulse. With 1,000-2,000 trillion watt (petawatt) lasers coming on line in the next few years and this new multi-cm acceleration distance possibility it is not beyond the realm of the plausible to expect to see hundred GeV, possibly even TeV energies coming out of these things. It takes the Stanford linear electron accelerator 2 miles to accelerate its 50 GeV electron positron beams! What we are witnessing is nothing short of a revolution in particle acclerators that will open up new frontiers of high TeV scale particle physics faster than anyone ever thought possible. This is the sort of breakthrough that happens once in 3 or 4 decades.... if you're lucky.

Sadly, the responses to this confirm

[Flying+pig]

That we do have a real crisis in physics education. (Here in the UK, having had to pay bonuses to attract maths teachers, the Government is now making similar efforts with physics - rather late.)

Reading the responses, there is frequently a lack of understanding of just how big this stuff is, just what it takes to produce things like wakefield accelerators and the difference between instantaneous power in watts and available energy.

Which reminds me of a true story. One company I worked for, the MD (aka CEO) decided we had to have a carbon dioxide laser to replace the ruby laser in one of our products. He talked to an academic researcher and asked how big the laser would need to be. The researcher said 10cm long and was promptly hired.

Six months later he had a prototype. The laser was a ceramic tube with fittings on a stand, genuinely about 150mm long with the fittings. Behind it was a room full of high voltage equipment, giant capacitors, carbon dioxide cylinders, extractor fans and, in fact, a water cooling system connected to a pressure main.

It took the MD a litle time to realise that this stuff was all part of making the laser go. He then asked when it would all be reduced in size to fit into a hand held box. The researcher's response? "You never told me you wanted the electrics to go in a box. You just said you wanted a four inch long laser."

A slight misunderstanding

[Attila+the+Bun]

PET scans don't use accelerated positrons. A radioisotope is injected into the patient, which emits a positron when it decays. The positron immediately annihilates with an electron and emits two gamma rays. The gamma rays are detected and used to build the scan. To make the radioisotope you need a proton accelerator, but these are already very compact at 2-3m diameter, and anyway don't need to be near the patient.

Fusion, of course, has nothing to do with accelerating electrons.

I thought geeks knew this stuff, or do they only need to pretend these days?