By Oliver Peckham
Newswise — Rewind to 2006. Electric vehicles (EVs) were emerging, but—despite mounting pressure to decarbonize the energy sector—the research community had not broadly recognized the importance of energy storage. At Pacific Northwest National Laboratory (PNNL), battery research was practically non-existent.
Today, PNNL is lauded for its battery research, leading several major energy storage programs for the Department of Energy (DOE). So: how did PNNL go from a new player to a leader in state-of-the-art storage for EVs and the grid?
Plugging in
In the mid-2000s, PNNL posed a daunting question: what was the most important problem its researchers could solve with their expertise in materials sciences?
A group led by Jun Liu—at the time, a PNNL materials scientist and laboratory fellow—coordinated a year of brainstorming. Through discussions with experts from laboratories, industry, and government, the group landed on an answer: energy storage. With renewable energy booming and fossil fuel frustration growing, the country needed reliable, powerful batteries—not just for transportation, but for the grid, as well.
The team scoped the initiative, conducting the first-ever quantitative analysis of domestic energy storage needs and mapping the intellectual property landscape to understand where the U.S. and PNNL could play leadership roles.
“PNNL had strengths in materials sciences, characterization tools, and simulations—but we needed a strategy to apply and expand those capabilities to address the scientific challenges in energy storage,” said Liu, now a Battelle Fellow who holds a joint appointment with the University of Washington.
In 2007, PNNL launched the Transformational Materials Science Initiative, a five-year, $7 million internal investment led by Liu and Jud Virden, who now serves as Associate Laboratory Director for Energy and Environment.
“The initiative really kickstarted our efforts in grid energy storage,” said Virden. “It allowed us to bring researchers from different disciplines together to focus on key scientific challenges."
Powering up
Early research under the initiative—on lithium and silicon anodes, sulfur-based batteries, high-voltage cathodes, functional electrolytes, and more—built fundamental knowledge to support next-generation batteries">battery technologies.
Projects ran the gamut from vehicle battery compositions (such as lithium-oxygen and lithium-sulfur) to grid-suited redox flow batteries that prioritized energy capacity (watt-hours) over energy density (watt-hours per cubic meter). PNNL developed capabilities to monitor battery degradation, including the unprecedented ability to use electron microscopes to watch battery capacity fade in real-time.
Other battery work poured in. DARPA funded PNNL research on primary high-energy lithium-air batteries. PNNL won the first award issued under the ARPA-E program for a proposal to reduce the operating temperatures of sodium-based batteries—research that led to those batteries operating at 50% lower temperatures.
DOE’s Vehicle Technologies Office (VTO) selected PNNL proposals for competitive battery programs, and the Office of Electricity (OE) chose PNNL for its first major investment in grid energy storage research. Through the latter project, PNNL developed electrolytes that improved batteries’ energy densities and operating temperatures. Those electrolytes are now licensed to several companies.
In the early 2010s, PNNL’s battery researchers teamed with other national laboratories and the Office of Science to coordinate energy storage research. In 2012, this effort was formalized when the DOE—seeing value in combining this expertise—launched the Joint Center for Energy Storage Research with PNNL as a partner.
Building capacity
As interest in EVs grew, battery range posed concerns. In 2016, the DOE selected a PNNL-led team to lead one of the largest EV battery research programs in the world: the Battery500 Consortium. The program, directed by Liu, aims to help create rechargeable lithium-metal EV batteries, delivering 500 watt-hours per kilogram—twice the current best-in-class—across 1,000 charge-discharge cycles.
The consortium’s first phase produced a prototype 350 watt-hour/kilogram lithium-metal battery with a lifetime of 600 cycles—a record-setting step toward lighter, longer-lasting, and less expensive EVs. Now in its second phase, the consortium has started demonstrating 400-450 watt-hour/kilogram batteries with stable cycling, nearing its headline goal.
In 2019, two of the consortium’s principal investigators—John Goodenough (a professor at The University of Texas at Austin) and Stan Whittingham—received the Nobel Prize in Chemistry for pioneering battery research.
“Battery500 has been a great collaborative effort, where we are making key breakthroughs without the hype that is all too common these days,” said Whittingham, a distinguished professor of chemistry at Binghamton University. “However, I have found the most rewarding part—in addition to the scientific accomplishments—has been watching the junior scientists grow and take key leadership positions.”
“The consortium’s success isn’t just in developing next-generation batteries,” Liu added. “It’s also in how we identified scientific problems, aligned resources to address challenges, improved how people worked together—even how we set community standards for how to conduct battery research.”
Generating momentum
Now far-reaching, PNNL’s energy storage programs have produced countless patent applications and high-impact papers. The Lab’s breakthroughs—many licensable—address longevity, capacity, and cold-weather performance, and have improved batteries">technologies from batteries">lithium-ion and lithium-metal batteries to flow and batteries-horizon">sodium-ion batteries.
“PNNL’s approach was to integrate fundamental research with practical applications and collaborate with others,” Virden said. “The integration and coordination from scientific discovery to technology development enables PNNL to have an enormous impact in the energy storage community.”
PNNL’s energy storage laboratories are now packed with highly cited—and frequently lauded—researchers. Some scientists hired through the 2007 initiative are now senior researchers at PNNL, leading national battery programs and cultivating new talent. (To that end, PNNL also offers internships and fellowships in energy storage.)
Current affairs
Increasingly, PNNL works with partners like batteries">Albemarle Corporation and Applied Materials to de-risk batteries">materials manufacturing and deploy new storage technologies in the real world. “The PNNL thread is there from the high-quality scientific papers all the way to these industrial investments,” Virden said.
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About PNNL
Pacific Northwest National Laboratory draws on its distinguishing strengths in chemistry, Earth sciences, biology and data science to advance scientific knowledge and address challenges in sustainable energy and national security. Founded in 1965, PNNL is operated by Battelle for the Department of Energy’s Office of Science, which is the single largest supporter of basic research in the physical sciences in the United States. DOE’s Office of Science is working to address some of the most pressing challenges of our time. For more information, visit https://energy.gov/science. For more information on PNNL, visit PNNL's News Center. Follow us on Twitter, Facebook, LinkedIn and Instagram.