Today we can see inside seemingly impossible places—nuclear reactors, volcanoes, tsunamis, hurricanes, and Egypt’s Great Pyramid of Giza—thanks to muon imaging. This technique uses naturally occurring subatomic particles called muons, which can penetrate far deeper than possible with x rays through material as thick and dense as 30-meter concrete walls.
But this process is also slow. Due to the low flux of naturally occurring muons, these images require exposure times on the order of months. Scientists at Lawrence Livermore National Laboratory (LLNL) are working to change that with a new initiative called Intense and Compact Muon Sources for Science and Security (ICMuS2).
Partnering with industry and academic researchers, the initiative seeks to rapidly generate these particles using high power lasers. The project is funded by the Defense Advanced Research Projects Agency’s Muons for Science and Security Program.
“Muons hold great potential across a range of applications,” said Jeff Wisoff, Principal Associate Director at LLNL’s National Ignition Facility and Photon Science Directorate. “This project will harness the lab’s world-class laser technology and expertise to lay the groundwork for imaging breakthroughs.”
Led by Brendan Reagan of LLNL’s NIF and Photon Science Advanced Photon Technologies program, ICMuS2 will develop a technical design for a portable, laser-based muon emitter with orders of magnitude greater flux than naturally occurring muons that can be used in imaging across a wide range of applications. These include special nuclear materials detection, mining, and geophysics among other uses.
“We have assembled a team of world leaders in the fields needed to meet the ambitious goals of DARPA’s MuS2 Program,” Reagan said. “This multi-faceted project combines high-power laser development, high-energy particle physics, plasma physics, advanced numerical simulations on high performance computing (HPC) systems, and systems engineering and integration. This is an exciting program that highlights the science and technology capabilities of the lab and the expertise of our partners.”
This work is carried out in partnership with the Extreme Light Infrastructure ERIC (ELI) at the ELI Beamlines Facility in the Czech Republic near Prague, to which LLNL delivered the High-Repetition-Rate Advanced Petawatt Laser System (HAPLS), Colorado State University (CSU), University of Maryland (UMD), Lockheed Martin, XUV Lasers, and Lawrence Berkeley National Laboratory.
Initial experiments will be conducted using UMD-developed plasma waveguides at CSU‘s Advanced Laser for Extreme Photonics (ALEPH) high-rep-rated petawatt laser facility. High energy acceleration and muon generation experiments will be conducted at the ELI Beamlines Facility using their L4 ATON 10 PW laser facility.
The ATON laser is not only among the world’s most powerful lasers at 10 PW, it is the most energetic of the short pulse lasers. This makes it ideal for creating an extreme environment for laser wakefield acceleration, paving the way for previously unattained electron energies, as high as 100 GeV. That creates optimal conditions for muon production.
This strategic advancement transcends scientific boundaries and strengthens collaboration between ELI and its esteemed partners in the United States. This partnership fosters a dynamic environment for knowledge exchange and the cultivation of innovative ideas, benefiting all parties involved.
“Global partnerships are a key aspect of ELI’s strategy and this builds on an already strong relationship we have with US partners,” says Allen Weeks, ELI’s Director General. “Participating in a DARPA funded project is exciting because we can aim high to achieve something bold.”
The muon detectors will be developed by CSU’s Physics Department High Energy Physics Group under the direction of Professor John Harton. “This project is a grand challenge for particle physics detection,” said Harton. “The muon particles are outnumbered by huge factors by other particles, and we are using all the tools in the box to sift them out. This is particle physics with a practical application, and we are glad to be involved.”
Aspects of this initiative build upon the Big Aperture Thulium (BAT) laser technology developed through LLNL’s Lab Directed Research and Development (LDRD) program and investments in laser-driven accelerators made by the U.S. Department of Energy Office of Science’s Offices of High Energy Physics and Accelerator Research & Development (R&D) and Production (ARDAP).
“The LDRD program pushes the frontiers in science and technology,” said Doug Rotman, LDRD program director at the Lab. “Through this project, early-stage high risk investments in laser technology are helping deliver science discovery and improve national security.”
The first phase of this four-year program will focus on proof-of-principle experiments and making a clear demonstration of laser-produced muons. The second phase will seek to demonstrate high energy muon production along with a design for a transportable muon source.