More than 300 megawatts of large, cargo container-sized sodium-beta batteries are running in the United States, Japan and Europe, according to Dupont Energy Consulting. They often store electricity generated by rows of solar panels and wind turbines. However, their broader use has been limited because of the high operating temperature.

(ZEBRA batteries have been used in electric vehicles, but thermal management is always an issue. GE is working to commercialize its Durathon sodium-metal halide batteries in a variety of heavy-duty applications, including transportation, e.g., earlier post.)

Commercial sodium–sulphur or sodium–metal halide batteries typically need an operating temperature of 300–350 °C, partly due to the poor wettability—i.e., the ability to coat—of liquid sodium on the surface of beta alumina, the researchers note. Molten sodium resists covering beta alumina’s surface when it’s below 400 ˚C, causing sodium to curl up like a drop of oil in water, making the battery less efficient.

Such high operating temperatures requires sodium-beta batteries to use more expensive materials and shortens their operating lifespans. For decades researchers have tried to overcome this by applying different coatings to the membrane.

Running at lower temperatures can make a big difference for sodium-beta batteries and may enable batteries to store more renewable energy and strengthen the power grid.

—Xiaochuan Lu, lead author

Lu and his PNNL colleagues took an entirely different approach to the wettability problem: modifying the negative electrode. Instead of using pure sodium, they experimented with sodium alloys, or sodium blended with other metals. The team determined a liquid sodium-cesium alloy spreads out well on the beta alumina membrane.

PNNL’s new electrode material enables the battery to operate at lower temperatures. Instead of the 350 ˚C at which traditional sodium-beta batteries operate, a test battery with the new electrode worked well at 150 ˚C, with a power capacity of 420 milliampere-hours per gram, matching the capacity of the traditional design.

Batteries with the new alloy electrode also retain more of their original energy storage capacity. After 100 charge and discharge cycles, a test battery with PNNL’s electrode maintained about 97 percent of its initial storage capacity, while a battery with the traditional, sodium-only electrode maintained 70 percent after 60 cycles.

A battery with a lower operating temperature can also use less expensive materials such as polymers—which would melt at 350 ˚C—for its external casing instead of steel. Using less expensive and sensitive materials would also help streamline the battery's manufacturing process. This offsets some of the increased cost associated with using cesium, which is more expensive than sodium.

The PNNL research team is now building a larger electrode to test with a larger battery to bring the technology closer to the scale needed to store renewable energy.

This research was supported by DOE’s Office of Electricity Delivery and Energy Reliability and internal PNNL funding.

Resources

• Xiaochuan Lu, Guosheng Li, Jin Y. Kim, Donghai Mei, John P. Lemmon, Vincent L. Sprenkle, Jun Liu (2014) “Liquid Metal Electrode to Enable Ultra-Low Temperature Sodium0Beta Alumina Batteries for Renewable Energy Storage,” Nature Communications doi: 10.1038/ncomms5578