Artistic rendering of Argonne’s photo-excitation technology for fast recharging of lithium-ion batteries (Image by Argonne National Laboratory)

Researchers at the U.S. Department of Energy’s (DOE) Argonne National Laboratory have reported a new mechanism to speed up the charging of lithium-ion batteries for electric vehicles. Simply exposing the cathode to a beam of concentrated light — for example, the white light from a xenon lamp — lowers the battery charging time by a remarkable factor of two or more. If commercialized, such technology could be a game changer for electric vehicles.

Owners of electric vehicles are well aware of “range anxiety” as the charge level runs low or the location of the closest charging station seems too distant. Fast charging remains a critical challenge if such vehicles are ever to capture a large segment of the transportation market. Charging for an electric car on empty typically takes about eight hours.

Special supercharging stations now exist that achieve ultrafast charging of electric vehicles by delivering a much higher current to the battery. Passing too much current over too short a time, however, degrades battery performance.

Typically, lithium-ion batteries for vehicles are slowly charged to obtain a complete electrochemical reaction. This reaction involves removing lithium from the oxide cathode and inserting it into the graphite anode. Today’s lithium-ion batteries work in a dark state, with the electrodes housed in a case. Argonne’s photo-assisted technology would use a transparent container that allows concentrated light to illuminate the battery electrodes during charging.

To probe the charge process, the research team crafted small lithium-ion cells (“coin cells”) with transparent quartz windows. They then tested these cells with and without white light shining through the window onto the cathode, which was made from a lithium manganese oxide (LMO), abbreviated as LiMn2O4. The key ingredient in this favorable reaction is the interplay of light with LMO, a semiconducting material known to interact with light. While absorbing the photons in the light during charging, the element manganese in the LMO changes its charge state from trivalent to tetravalent (Mn3+ to Mn4+). In response, lithium ions eject faster from the cathode than would occur without the photon-excitation process.

This condition drives the battery reaction faster. The team found that the faster reaction resulted in faster charging without degrading battery performance or cycle life. The Vehicle Technologies Office of the DOE Office of Energy Efficiency and Renewable Energy has identified fast charge as a critical challenge in ensuring mass adoption of electric vehicles with a goal of 15-min. recharge time, and this research could be a key to making this possible.

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