Newswise — Researchers at the Department of Energy’s SLAC National Accelerator Laboratory are playing key roles in two recently funded computing projects with the goal of developing cutting-edge scientific applications for future exascale supercomputers that can perform at least a billion billion computing operations per second – 50 to 100 times more than the most powerful supercomputers in the world today.

The first project, led by SLAC, will develop computational tools to quickly sift through enormous piles of data produced by powerful X-ray lasers. The second project, led by DOE’s Lawrence Berkeley National Laboratory (Berkeley Lab), will reengineer simulation software for a potentially transformational new particle accelerator technology, called plasma wakefield acceleration.

The projects, which will each receive $10 million over four years, are among 15 fully-funded application development proposals and seven proposals selected for seed funding by the DOE’s Exascale Computing Project (ECP). The ECP is part of President Obama’s National Strategic Computing Initiative and intends to maximize the benefits of high-performance computing for U.S. economic competiveness, national security and scientific discovery.

“Many of our modern experiments generate enormous quantities of data,” says Alex Aiken, professor of computer science at Stanford University and director of the newly formed SLAC Computer Science division, who is involved in the X-ray laser project. “Exascale computing will create the capabilities to handle unprecedented data volumes and, at the same time, will allow us to solve new, more complex simulation problems.”

Analyzing ‘Big Data’ from X-ray Lasers in Real Time

X-ray lasers, such as SLAC’s Linac Coherent Light Source (LCLS) have been proven to be extremely powerful “microscopes” that are capable of glimpsing some of nature’s fastest and most fundamental processes on the atomic level. Researchers use LCLS, a DOE Office of Science User Facility, to create molecular movies, watch chemical bonds form and break, follow the path of electrons in materials and take 3-D snapshots of biological molecules that support the development of new drugs.

At the same time X-ray lasers also generate giant amounts of data. A typical experiment at LCLS, which fires 120 flashes per second, fills up hundreds of thousands of gigabytes of disk space. Analyzing such a data volume in a short amount of time is already very challenging. And this situation is set to become dramatically harder: The next-generation LCLS-II X-ray laser will deliver 8,000 times more X-ray pulses per second, resulting in a similar increase in data volumes and data rates. Estimates are that the data flow will greatly exceed a trillion data ‘bits’ per second, and require hundreds of petabytes of online disk storage.

As a result of the data flood even at today’s levels, researchers collecting data at X-ray lasers such as LCLS presently receive only very limited feedback regarding the quality of their data.

“This is a real problem because you might only find out days or weeks after your experiment that you should have made certain changes,” says Berkeley Lab’s Peter Zwart, one of the collaborators on the exascale project, who will develop computer algorithms for X-ray imaging of single particles. “If we were able to look at our data on the fly, we could often do much better experiments.”

Amedeo Perazzo, director of the LCLS Controls & Data Systems Division and principal investigator for this “ExaFEL” project, says, “We want to provide our users at LCLS, and in the future LCLS-II, with very fast feedback on their data so that can make important experimental decisions in almost real time. The idea is to send the data from LCLS via DOE’s broadband science network ESnet to NERSC, the National Energy Research Scientific Computing Center, where supercomputers will analyze the data and send the results back to us – all of that within just a few minutes.” NERSC and ESnet are DOE Office of Science User Facilities at Berkeley Lab.

X-ray data processing and analysis is quite an unusual task for supercomputers. “Traditionally these high-performance machines have mostly been used for complex simulations, such as climate modeling, rather than processing real-time data” Perazzo says. “So we’re breaking completely new ground with our project, and foresee a number of important future applications of the data processing techniques being developed.”

This project is enabled by the investments underway at SLAC to prepare for LCLS-II, with the installation of new infrastructure capable of handling these enormous amounts of data.

A number of partners will make additional crucial contributions.

“At Berkeley Lab, we’ll be heavily involved in developing algorithms for specific use cases,” says James Sethian, a professor of mathematics at the University of California, Berkeley, and head of Berkeley Lab’s Mathematics Group and the Center for Advanced Mathematics for Energy Research Applications (CAMERA). “This includes work on two different sets of algorithms. The first set consists of well-established analysis programs that we’ll reconfigure for exascale computer architectures, whose larger computer power will allow us to do better, more complex physics. The other set is brand new mathematics and algorithms to handle emerging technologies such as single-particle imaging, which is being designed to allow scientists to study the atomic structure of single bacteria or viruses in their living state.”

The “ExaFEL” project led by Perazzo will take advantage of Aiken’s newly formed Stanford/SLAC team, and will collaborate with researchers at Los Alamos National Laboratory to develop systems software that operates in a manner that optimizes its use of the architecture of the new exascale computers.

“Supercomputers are very complicated, with millions of processors running in parallel,” Aiken says. “It’s a real computer science challenge to figure out how to use these new architectures most efficiently.”

Finally, ESnet will provide the necessary networking capabilities to transfer data between the LCLS and supercomputing resources. Until exascale systems become available in the mid-2020s, the project will use NERSC’s Cori supercomputer for its developments and tests.

Simulating the Future of Particle Accelerators

The second project aims at making use of exascale computing capabilities to simulate plasma wakefield accelerators. In this technology, charged particles such as electrons and their antimatter siblings, positrons, gain energy as they “surf” on waves of hot, ionized gas (known as ‘plasma’).

The plasma wave is created by passing either an extremely powerful laser beam or a very energetic beam of electrons through the plasma. The first approach is being tested at facilities like Berkeley Lab’s BELLA Center, the other at SLAC’s Facility for Advanced Experimental Tests (FACET), also a DOE Office of Science User Facility. Plans for a FACET-II upgrade are currently under DOE review.

Due to the extremely large accelerating electric fields in plasma waves, which are 1,000 times stronger than in conventional accelerators, the technology could lead to much more compact and potentially less expensive particle accelerators for X-ray laser science and particle physics.

“To design plasma accelerators and better understand the complex processes inside plasmas, we frequently do demanding computer simulations,” says Jean-Luc Vay, a senior physicist at Berkeley Lab, who is the principal investigator for this exascale project. “Simulations of a single plasma stage, which do not even take into account all complexity, take days to weeks on today’s supercomputers. If we ever want to be able to run simulations for future particle colliders, which will require up to 100 stages chained together, exascale computing is absolutely necessary.”

The goal of the project is to take Berkeley Lab’s existing accelerator simulation code “Warp” and combine it with a high-resolution refinement tool named “BoxLib” to form a new code “WarpX” designed for the future exascale computing architectures. Until these become available, tests will be performed on NERSC’s Cori supercomputer.

“The code developments will be largely done at Berkeley with contributions from Lawrence Livermore National Laboratory,” says Cho-Kuen Ng, head of the Computational Electrodynamics Department in SLAC’s Technology Innovation Directorate. “SLAC has decades of experience with high-performance computing in the simulation of accelerators, and we’ll contribute, among other activities, by helping optimize the new code and making sure it runs fast and efficiently.”

Mark Hogan, who leads SLAC’s plasma acceleration efforts, says, “The approaches at SLAC and Berkeley of creating plasma waves are quite different. Our lab’s role in this project is also to ensure that Berkeley’s codes will be applicable to particle-driven plasma accelerators – a technology that we’ll continue to develop at FACET-II.”

SLAC is a multi-program laboratory exploring frontier questions in photon science, astrophysics, particle physics and accelerator research. Located in Menlo Park, Calif., SLAC is operated by Stanford University for the U.S. Department of Energy's Office of Science. For more information please visit slac.stanford.edu.

SLAC National Accelerator Laboratory is supported by the Office of Science of the U.S. Department of Energy. The 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 science.energy.gov.