Structural water in tungsten oxide yields higher and more efficient energy storage.
(Image courtesy of José Manuel Suárez.)
Researchers have found that a material which incorporates atomically thin layers of water is able to store and deliver energy much more quickly than the same material that doesn’t include the water layers.
The finding raises some interesting questions about the behavior of liquids when confined at this scale and holds promise for shaping future energy-storage technologies.
“This is a proof of concept, but the idea of using water or other solvents to ‘tune’ the transport of ions in a layered material is very exciting,” said Veronica Augustyn, an assistant professor of materials science and engineering at North Carolina State University and corresponding author of a paper describing the work. “The fundamental idea is that this could allow an increased amount of energy to be stored per unit of volume, faster diffusion of ions through the material, and faster charge transfer.
“Again, this is only a first step, but this line of investigation could ultimately lead to things like thinner batteries, faster storage for renewable-based power grids, or faster acceleration in electric vehicles,” Augustyn said.
“The goal for many energy-storage researchers is to create technologies that have the high energy density of batteries and the high power of capacitors,” said James Mitchell, a Ph.D. student at NC State and lead author of the paper. “Pseudocapacitors like the one we discuss in the paper may allow us to develop technologies that bridge that gap.”
For this work, the researchers compared two materials: a crystalline tungsten oxide and a layered, crystalline tungsten oxide hydrate—which consists of crystalline tungsten oxide layers separated by atomically thin layers of water.
When charging the two materials for 10 minutes, the researchers found that the regular tungsten oxide stored more energy than the hydrate. But when the charging period was only 12 seconds, the hydrate stored more energy than the regular material. One thing that’s intriguing, the researchers say, is that the hydrate stored energy more efficiently.
“Incorporating these solvent layers could be a new strategy for high-powered energy-storage devices that make use of layered materials,” Augustyn said. “We think the water layer acts as a pathway that facilitates the transfer of ions through the material.
“We are now moving forward with National Science Foundation-funded work on how to fine-tune this so-called ‘interlayer,’ which will hopefully advance our understanding of these materials and get us closer to next-generation energy-storage devices.”
The research is published under the title, “Transition from Battery to Pseudocapacitor Behavior via Structural Water in Tungsten Oxide,” in the journal Chemistry of Materials.
For more energy storage news, read about New Battery Technology for Renewable Energy and Electric Vehicles.