'Erratic' Lasers Pave Way for Tabletop Accelerators
Computations at NERSC show how multiply charged metal ions impact battery capacity
June 30, 2014
Contact: Kathy Kincade, +1 510 495 2124, [email protected]
Making a tabletop particle accelerator just got easier. A new study shows that certain requirements for the lasers used in an emerging type of small-area particle accelerator can be significantly relaxed. Researchers hope the finding could bring about a new era of accelerators that would need just a few meters to bring particles to great speeds, rather than the many kilometers required of traditional accelerators.
The research, from scientists at the U.S. Department of Energy’s (DOE) Lawrence Berkeley National Laboratory (Berkeley Lab), was presented in the May special issue of Physics of Plasmas. Their work was supported by supercomputing resources at the National Energy Research Scientific Computing Center (NERSC).
Traditional accelerators, like the Large Hadron Collider where the Higgs boson was recently discovered, rely on high-power radio-frequency waves to energize electrons. The new type of accelerator, known as a laser-plasma accelerator, uses pulses of laser light that blast through a soup of charged particles known as a plasma; the resulting plasma motion, which resemble waves in water, accelerates electrons riding atop the waves to high speeds.
The problem, however, is creating a laser pulse that’s powerful enough to compete with the big accelerators. In particular, lasers need to have the capability to fire a high-energy pulse thousands of times a second. Today’s lasers can only manage one pulse per second at the needed energy levels.
“If you want to make a device that’s of use for particle physics, of use for medical applications, of use for light source applications, you need repetition rate,” explains Wim Leemans, director of the Accelerator and Fusion Research Division and director of the BELLA Center at Berkeley Lab. In January of 2013, the DOE held a workshop on laser technology for accelerators. At the time, says Leemans, the big question was how to get from the current technology to the scaled up version.
Conventional wisdom holds that many smaller lasers, combined in a particular way, could essentially create one ultra powerful pulse. In theory, this sounds fine, but the practical requirements to build such a system have seemed daunting. For instance, it was believed that the light from the smaller lasers would need to be precisely matched in color, phase, and other properties in order to produce the electron-accelerating motion within the plasma.
“We thought this was really challenging,” says Leemans, “We thought, you need this nice laser pulse, and everything needs to be done properly to control the laser pulse.”
A Hodgepodge of Laser Light
But the new Berkeley Lab study has found this isn’t the case. Paper co-authors Carlo Benedetti, Carl Schroeder, Eric Esarey and Leemans wanted to see what an erratic laser pulse would actually do inside a plasma. Guided by theory and using computer simulations on NERSC’s Edison and Hopper systems to test various scenarios, the researchers looked at how beams of various colors and phases—basically a hodgepodge of laser light—affected the plasma. They soon discovered that, no matter the beam, the plasma didn’t care.
“The plasma is a medium that responds to a laser, but it doesn’t respond immediately,” says Benedetti, a physicist at Berkeley Lab. The light is just operating on a faster time scale and a smaller length scale, he explains. All of the various interference patterns and various electromagnetic fields average out in the slow-responding plasma medium. In other words, once laser light gets inside the plasma, many of the problems disappear.
“As an experimentalist for all these years we’re trying to make these perfect laser pulses, and maybe we didn’t need to worry so much,” says Leemans. “I think this will have a big impact on the laser community and laser builders because all of a sudden, they’ll think of approaches where before hand all of us said, ‘No, no, no. You can’t do that.’ This new result says, well maybe you don’t have to be all that careful.”
Leemans says the ball is back in the experimentalists’ and laser builders’ court to prove that the idea can work. In 2006, he and his team demonstrated a three-centimeter long plasma accelerator. Where a traditional accelerator can take kilometers to drive an electron to 50 giga-electron volts (GeV), Leemans and team showed that a mini-laser plasma accelerator could get electrons to 1 GeV in just three centimeters with a laser pulse of about 40 terawatt. To go to higher electron energies, in 2012, a larger more powerful laser was installed at the Berkeley Lab Laser Accelerator (BELLA) facility with a petawatt pulse (1 quadrillion watts) that lasts 40 femtoseconds, which is now being used in experiments that aim at generating a 10 GeV beam.
NERSC simulations over the past year supported new experiments on multi-GeV beams on the BELLA laser, noted Esarey, deputy director of the BELLA Center. The simulations provide information—such as nonlinear plasma response, particle trapping, and self-consistent laser propagation and beam acceleration—to understand and improve these new accelerators.
Still, the goal of a high-repetition rate, 10-GeV laser-plasma accelerator that fires a thousand pulses or more per second, is at least five to ten years away, says Leemans. But a new project called k-BELLA (k is for kilohertz) is in the works that will use the principles of combined, messy laser light sources to produce fast, more powerful laser pulses.
“Once we synthesize a pulse at higher repetition rates,” says Leemans, “we will be on our way towards a kilohertz GeV laser plasma accelerator.”
This work was supported by the DOE Office of Science.
About Computing Sciences at Berkeley Lab
High performance computing plays a critical role in scientific discovery, and researchers increasingly rely on advances in computer science, mathematics, computational science, data science, and large-scale computing and networking to increase our understanding of ourselves, our planet, and our universe. Berkeley Lab’s Computing Sciences Area researches, develops, and deploys new foundations, tools, and technologies to meet these needs and to advance research across a broad range of scientific disciplines.
Founded in 1931 on the belief that the biggest scientific challenges are best addressed by teams, Lawrence Berkeley National Laboratory and its scientists have been recognized with 13 Nobel Prizes. Today, Berkeley Lab researchers develop sustainable energy and environmental solutions, create useful new materials, advance the frontiers of computing, and probe the mysteries of life, matter, and the universe. Scientists from around the world rely on the Lab’s facilities for their own discovery science. Berkeley Lab is a multiprogram national laboratory, managed by the University of California for the U.S. Department of Energy’s Office of Science.
DOE’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit energy.gov/science.