From the “E.O. Lawrence would be jealous department” and the University of Texas Austin comes this bit of interesting news (h/t to “View From the Solent”). Full disclosure, I made a cyclotron myself and went to the National Science Fair with it in 1975. It was about the size of desk, and I powered its magnet system with my dad’s DC welder. I got about 2 MeV out of it. – Anthony
Particle Accelerator That Can Fit on a Tabletop Opens New Chapter for Science Research
AUSTIN, Texas — 
Physicists at The University of Texas at Austin have built a tabletop particle accelerator that can generate energies and speeds previously reached only by major facilities that are hundreds of meters long and cost hundreds of millions of dollars to build.
“We have accelerated about half a billion electrons to 2 gigaelectronvolts over a distance of about 1 inch,” said Mike Downer, professor of physics in the College of Natural Sciences. “Until now that degree of energy and focus has required a conventional accelerator that stretches more than the length of two football fields. It’s a downsizing of a factor of approximately 10,000.”
The results, which were published this week in Nature Communications, mark a major milestone in the advance toward the day when multi-gigaelectronvolt (GeV) laser plasma accelerators are standard equipment in research laboratories around the world.
Downer said he expects 10 GeV accelerators of a few inches in length to be developed within the next few years, and he believes 20 GeV accelerators of similar size could be developed within a decade.
Downer said that the electrons from the current 2 GeV accelerator can be converted into “hard” X-rays as bright as those from large-scale facilities. He believes that with further refinement they could even drive an X-ray free electron laser, the brightest X-ray source currently available to science.
A tabletop X-ray laser would be transformative for chemists and biologists, who could use the bright X-rays to study the molecular basis of matter and life with atomic precision, and femtosecond time resolution, without traveling to a large national facility.
“The X-rays we’ll be able to produce are of femtosecond duration, which is the time scale on which molecules vibrate and the fastest chemical reactions take place,” said Downer. “They will have the energy and brightness to enable us to see, for example, the atomic structure of single protein molecules in a living sample.”
To generate the energetic electrons capable of producing these X-rays, Downer and his colleagues employed an acceleration method known as laser-plasma acceleration. It involves firing a brief but intensely powerful laser pulse into a puff of gas.
“To a layman it looks like low technology,” said Downer. “All you do is make a little puff of gas with the right density and profile. The laser pulse comes in. It ionizes that gas and makes the plasma, but it also imprints structure in it. It separates electrons from the ion background and creates these enormous internal space-charge fields. Then the charged particles emerge right out of the plasma, get trapped in those fields, which are racing along at nearly the speed of light with that laser pulse, and accelerate in them.”
The interior of the vacuum chamber in which the acceleration occurs. The laser beam arrives from the right. The gas cell, within which the acceleration of electrons occurs, is in the center of the chamber. The actual acceleration occurs over a distance of about an inch.
Downer compared it to what would happen if you threw a motorboat into a lake with its engines churning. The boat (the laser) makes a splash, then creates a wave as it moves through the lake at high speed. During that initial splash some droplets (charged particles) break off, get caught up in the wave and accelerate by surfing on it.
“At the other end of the lake they get thrown off into the environment at incredibly high speeds,” said Downer. “That’s our 2 GeV electron beam.”
Former UT Austin physicist Toshiki Tajima and the late UCLA physicist John Dawson conceived the idea of laser-plasma acceleration in the late 1970s. Scientists have been experimenting with this concept since the early 1990s, but they’ve been limited by the power of their lasers. As a result the field had been stuck at a maximum energy of about 1 GeV for years.
Downer and his colleagues were able to use the Texas Petawatt Laser, one of the most powerful lasers in the world, to push past this barrier. In particular the petawatt laser enabled them to use gases that are much less dense than those used in previous experiments.
“At a lower density, that laser pulse can travel faster through the gas,” said Downer. “But with the earlier generations of lasers, when the density got too low, there wasn’t enough of a splash to inject electrons into the accelerator, so you got nothing out. This is where the petawatt laser comes in. When it enters low density plasma, it can make a bigger splash.”
Downer said that now that he and his team have demonstrated the workability of the 2 GeV accelerator, it should be only a matter of time until 10 GeV accelerators are built. That threshold is significant because 10 GeV devices would be able to do the X-ray analyses that biologists and chemists want.
“I don’t think a major breakthrough is required to get there,” he said. “If we can just keep the funding in place for the next few years, all of this is going to happen. Companies are now selling petawatt lasers commercially, and as we get better at doing this, companies will come into being to make 10 GeV accelerator modules. Then the end users, the chemists and biologists, will come in, and that will lead to more innovations and discoveries.”
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anna v says:
June 22, 2013 at 9:25 am
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The EU just lent Greece money so that Greece could use it to pay back banks etc in the large EU countries such as Germany and France, not to help the Greek economy or to fund infrasturcture improvements and structural changes. Effectively, the money was used to bail out German and in particular French banks which held a lot of Greek debt. Greece itself did not benefit at all; as you say, Greek debt is now higher (and, of course, unemployment higher and living standards lower) .
It did not help the other peritheries such as Spain and Italy. Indeed, it has made their fragile positions far worse. They contributed to the ‘loan’ being made to Greece, but they had no money to loan, so they had to go to the markets to borrow money at high rates (5 to 8% depending on timing) and Spain and Italy cannot afford to service those debts pushing them further into debt. It was OK for Germany since if it needed to borrow money to ‘loan’ to Greece, it did so at low interest rates of under 2%.
This is politics at its very worst.Conceiling the true purpose of the loan, ie., not to save Greece but to save the French banks in particular, and to a lesser extent German banks. It did nothing to assist Greece and it was madness to force Spain, Italy and Portugal to borrow money at high interest rates so they could contibute their share towards the Greek bailout, thereby making more likely not less likely that those Southern European countries would need bail outs.
Pity also the Cypriots. Much of their bank problems were caused by teh EU who were suggesting that it was safe to lend money to Greek banks and take out Greek bonds, and there would not be
haircuts for such investors. When the EU insisted that those with Greek bonds would have to take haircuts then Cyprus’s fate was sealed. Cyprus was the casualty of that decision.
Personally, I can’t understand why the Spanish banks have not collapsed. i would have expected that anyone with any money (say more than €10,000) would take their money out of these banks just in case the EU do another raid just like Cyprus but this time follow through with the take of a share of even small savings.
We read some really appalling stories about life in Greece (today there is a story about how middle class parents can’t afford to look after their kids and are placing them in orphanages). I just hope that things begin to improve but it is difficult to see how this can happen in the short term. I also really hope that Greece is not forced into selling all its assets. It will regret that.
“A table top x-ray laser”
One potential huge application for this would be micro tomography. At present desktop “microCT” exists (a commercial technology in its second decade) but its accuracy is hampered by the polychromatic x-rays from lab x-ray sources. For monochromatic tomography one has to go to a synchrotron.
But the small print which up to now has stopped this application is the tiny x-ray flux from x-ray lasers. One needs something more like continuous flux, femtosecond pulses are not much use here. For 3d image reconstruction one needs enough photons for good image signal/noise. About 10,000 photons detected per pixel, 10-16 million pixels in the camera, for several thousand projection images per scan.
If x-ray lasers could produce the goods on this scale, stably and reliably for several years, this would be a disruptive transformation of x-ray microtomography. So I would like to see the small print on flux and stability.
Who needs equipment like this in research laboratories? Scientists are moving away from doing science to proving dogma now. All they need are some models programmed to give the results that they want to prove…
Can’t help but recall this UPI headline from a few days ago “Terrorism radiation plot uncovered in Albany, N.Y.” ? Maybe it wasn’t so far fetched after all, Then again of course its always prudent to read between the lines on everything reported in the media before donning the tinfoil hat…
anna v
I know I’m probably preaching to the choir here and this isn’t a political site.
Best bet for Greece is to default, revert to the Drachma and walk away from the EU.
For years Germany has been financing your élites buying BMWs & Mercedes.
Bite back!
DaveE.
interesting…could this thing be used to power a thorium?