One Step Closer to Practical Fast Charging Batteries
Novel electrode materials have designed pathways for electrons and ions during the charge/discharge cycle.
The Science
Electrodes are critical parts of every battery architecture – charge too fast, and you can decrease the charge-discharge cycle life or damage the battery so it won’t charge anymore. Scientists built a new design and chemistry for electrodes. Their design involves advanced, nanostructured electrodes containing molybdenum disulfide and carbon nanofibers. These composite materials have internal atomic-scale pathways. These paths are for both fast ion and electron transport, allowing for fast charging.
The Impact
The new battery electrodes provide several benefits. The electrodes allow fast charging. They also have stable charge/discharge behavior, so the batteries last longer. These electrodes show promise for practical electrical energy storage systems.
Summary
New battery electrodes based on nanostructured molybdenum disulfide combine the ability to charge in seconds with high capacity and long cycle life. Typical lithium-ion batteries charge slowly due to slow diffusion of lithium ions within the solid electrode. Another type of energy storage device (a.k.a., pseudocapacitors), which has similarities to the capacitors found in common electrical circuits, speeds up the charging process by using reactions at or near the electrode surface, thus avoiding slow solid-state diffusion pathways. Nanostructured electrodes allow the creation of large surface areas so that the battery can work more like a pseudocapacitor. In this work at the University of California, Los Angeles, scientists made nanostructured electrodes from a molybdenum disulfide-carbon composite. Many electrodes are based on metal oxides, but because sulfur more weakly interacts with lithium than oxygen, lithium atoms can move more freely in the metal sulfide than the metal oxide. The result is a battery electrode that shows high capacity and very fast charging times. The novel electrodes deliver specific capacities of 90 mAh/g (about half that of a typical lithium-ion battery cathode) charging in less than 20 seconds, and retain over 80 percent of their original capacity after 3,000 charge/discharge cycles. Capacities of greater than 180 mAh/g (similar to cathodes in conventional lithium-ion cells) are achieved at slower charging rates. The results have exciting implications for the development of fast-charging energy storage systems that could replace traditional lithium-ion batteries.
Contact
Prof. Sarah Tolbert
University of California, Los Angeles
tolbert@chem.ucla.edu
Funding
U.S. Department of Energy, Office of Science, Basic Energy Sciences (materials synthesis, structural characterization, and electrochemical measurements) and the Office of Naval Research (additional electrochemical measurements)
Publications
J.B. Cook, H.S. Kim, T.C. Lin, C.H. Lai, B. Dunn, and S.H. Tolbert, “Pseudocapacitive charge storage in thick composite MoS2 nanocrystal-based electrodes.” Advanced Energy Materials 7(2), 1601283 (2017). [DOI: 10.1002/aenm.201601283]
Highlight Categories
Performer: University
Additional: Technology Impact , Collaborations , Non-DOE Interagency Collaboration