SLAC National Accelerator Laboratory

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SLAC: Probing The Tiniest Building Blocks Of Matter, And More

SLAC is picured at night. Photos courtesy of SLAC National Accelerator Laboratory.

Long before there was the Large Hadron Collider and the Relativistic Heavy Ion Collider, there was the Stanford Linear Accelerator.

Stanford's particle collider, which opened in 1962, was the longest linear accelerator ever built (still is). It's helped scientists make countless discoveries about the tiniest building blocks of our universe; three Nobel Prizes have been awarded for discoveries made in part by scientists working at SLAC.

"There's no end to the amazing things going on here," says Michael Peskin, a professor of theoretical physics at SLAC.

In 1957, particle accelerators at Brookhaven and Berkeley were leading the way in the discoveries of new subatomic particles. Riding that wave, Stanford scientists proposed building an even more powerful collider. It would be two miles long and be able to accelerate electrons to 50 gigaelectron volts, much faster than any other accelerator of the day. It would also cost more than $100 million in 1957 dollars--at the time, the most expensive non-defense research venture in U.S. history.

Still, researchers were confident that the proposed linear accelerator would uncover answers, even if the answers were to questions that hadn't been asked yet. (At one point during a Congressional hearing, a senator asked one of the accelerator designers, Dr. Edward Ginzton, "Can you tell us precisely why you want to build this machine?" Dr. Ginzton replied, "Senator, if I knew the answer to that question we would not be proposing to build this machine."

The collider eventually got built and almost immediately began producing solid science. In 1968, scientists working at SLAC discovered the first quarks. Just a few years later in 1974, Burton Richter, working at SLAC, and a team at Brookhaven independently discovered the J/psi particle, and just a year later a team led by Martin Perl discovered the tau lepton. These three discoveries would eventually lead to Nobel prizes.

Around the same time, says Peskin, "Professor William Spicer noticed that the synchrotrons here emit X-rays at a rate which is...potentially a billion times more intense than one got from the standard equipment at the time. And so this enabled all kinds of new x-ray experiments, which were done here for the first time." The Linac Coherent Light Source, or LCLS, re-uses a third of SLAC's old accelerator (the other two thirds is dedicated to the FACET project, which is an R&D project for experimental beam physics.)

Now, SLAC's X-ray free-electron laser "has pretty much taken over the whole laboratory," Peskin says. The LCLS, when it opened, was a billion times brighter than any other X-ray source in existence, says Alan Fry, divison director, laser science and technology, for the LCLS. "It's the difference between a high-powered laser and moonlight." The LCLS also produces extremely short pulses that last just a few femtoseconds. "This is the time scale on which stuff actually happens at the molecular and atomic scale," Fry says. That means researchers can use the LCLS to create essentially stop-motion movies of molecules breaking apart or electrons redistributing themselves. Mike Minitti, a SLAC scientist whose “molecular movie” of 1,3-cyclohexadiene unfurling was on the cover of Physical Review Letters June 2015 , told the journal at the time that “This fulfills a promise of LCLS. Before your eyes,” he added, “a chemical reaction is occurring that has never been seen before in this way.”

Because scientists are clamoring for time with the LCLS (SLAC runs around the clock almost every day), and because there’s even more to be done with x-ray lasers, SLAC is building the LCLS-II, which will increase the number of x-ray pulses from 120 per second to a million times a second. It's under development now but won't open for another 5 or 6 years. When it does, researchers will be able to perform experiments in quantum chemistry, structural biology and surface physics, leading to new understandings of basic matter and new technologies and materials.

SLAC's equipment is used for more than just probing the properties of tiny particles. Scientists using SLAC's synchrotron radiation lightsource discovered the bone chemistry of Archaeopteryx and revealed a hidden manuscript written by Archimedes that had later been overwritten with 10th-century Greek Orthodox prayers. SLAC scientists are helping the development of an experiment that detects dark matter. Researchers are also hunting for ways to improve rechargeable batteries, develop better antibiotics, and even improve computer hard drives.

"It's always been an exciting place with people coming up with crazy ideas," Peskin says.

Fry agrees. "This is really only the beginning of the story of these machines and what they're going to be able to do and the science they're going to be able to produce."


Also See:

Atom Smasher Doesn't SLAC Offby Melinda Lee (The SPS Observer, Fall 2015)

This illustration shows atoms forming a tentative bond, a moment captured for the first time in experiments with an X-ray laser at SLAC National Accelerator Laboratory.
Stanford Synchrotron Radiation Lightsource (SSRL) scientists Piero Pianetta and Jacqueline Kerlegan inspect SSRL's newest X-ray microscope at Beamline 6-2.
This illustration depicts an experiment at SLAC that revealed how a protein from photosynthetic bacteria changes shape in response to light.