Gallaway Receives NSF CAREER Award
DiPietro Assistant Professor Joshua Gallaway, chemical engineering, was awarded a $400K NSF CAREER award for “Engineering electrochemical reversibility in disordered materials for high energy density batteries.” The project will conduct research on advanced battery materials that have the potential for greater energy density and cycle life, while operating in non-flammable water-based electrolytes.
Galloway joined Northeastern University in 2017 and earned his PhD at Columbia University in 2007. His research interests include electrochemical engineering, batteries and energy storage, energy sustainability.
Making Batteries Safe and Inexpensive for the Electrical Grid
For the past ten years, Joshua Gallaway, DiPietro assistant professor of Chemical Engineering, has been consumed with solving a unique electrochemical puzzle, one that has the potential to make widespread adoption of renewable energy a reality.
Gallaway’s work recently earned him a $400K National Science Foundation CAREER Award for “Engineering Electrochemical Reversibility in Disordered Materials for High Energy Density.” The award will help Gallaway and his team address the challenge of rechargeability of a battery material, manganese dioxide (MnO₂), that could speed the development of large, low cost, non-flammable batteries capable of powering the electrical grid.
“We’ve learned that you can make this material, MnO₂, rechargeable by doping it with other atoms,” Gallaway explains. “If you use bismuth—a high molecular weight atom—to dope the MnO₂ material, it becomes rechargeable. Then you can conceivably make batteries for the electrical grid that are inexpensive and safe.”
A scientific obsession
Although this phenomenon was originally discovered nearly 40 years ago by a research group at Ford working on an electrical vehicle battery, no one knows why bismuth makes MnO₂ rechargeable. “This is the scientific question that has me most obsessed,” says Gallaway.
To figure out this mystery, Gallaway and his team—six graduate students, a post doc and “an army of undergrads”—will make MnO₂ that has several different forms of bismuth doped into it. “The large part is synthesis work with different amounts of bismuth incorporated in different ways,” he says. “We are going to characterize that material, where it is and how much of it is there. We’ll cycle the material in different ways to see what happens to it and study the relationship between bismuth and the rest of the atoms.”
Aiding the team in watching materials while they’re doing electrochemistry is a synchrotron, a type of particle accelerator called NSLS-II and located on Long Island. “These facilities make very high-quality X-rays that are also very bright and very high energy,” explains Gallaway. “We use powerful X-rays from the synchrotron to focus on bismuth during charging and discharging of the battery to see what the bismuth is doing.”
Saving the world
Gallaway is also obsessed with another unique characteristic of the MnO₂/bismuth pairing: while cycling in a battery, the bismuth is initially ordered, showing general regularity, but it becomes disordered, and thus more difficult to characterize. “In the past, we looked at materials from an ordered perspective,” he says. “Now we look at these materials from the point of view of disorder, using different X-ray techniques…The point is knowing what bismuth is doing. Then we can engineer it to do better.”
Gallaway believes his research, if successful, “could save the world.” “If you believe that climate change is real, that it’s a problem, then you must stop making electricity with fossil fuels and you need something else,” he says. “Solar and wind power is not controllable. Basically, you make electricity when the sun shines and the wind blows. For that reason, when you make electricity, you need to put it somewhere where you can control it, for example, in a battery that stores electricity so you can release it whenever you want. These batteries are uniquely well suited to be in the grid.”
Award Abstract: NSF