All-solid sulfur-based battery outperforms lithium-ion technology
A
new all-solid lithium-sulfur battery developed by an Oak Ridge National
Laboratory team led by Chengdu Liang has the potential to reduce cost, increase
performance and improve safety compared with existing designs. Photo: Oak Ridge
National LaboratoryScientists at the U.S. Dept. of Energy (DOE)'s Oak Ridge
National Laboratory (ORNL) have designed and tested an all-solid lithium-sulfur
battery with approximately four times the energy density of conventional
lithium-ion technologies that power today's electronics.
The
ORNL battery design, which uses abundant low-cost elemental sulfur, also
addresses flammability concerns experienced by other chemistries.
"Our
approach is a complete change from the current battery concept of two
electrodes joined by a liquid electrolyte, which has been used over the last
150 to 200 years," says Chengdu Liang, lead author on the ORNL study
published in Angewandte Chemie International Edition.
Scientists
have been excited about the potential of lithium-sulfur batteries for decades,
but long-lasting, large-scale versions for commercial applications have proven
elusive. Researchers were stuck with a catch-22 created by the battery's use of
liquid electrolytes: On one hand, the liquid helped conduct ions through the
battery by allowing lithium polysulfide compounds to dissolve. The downside,
however, was that the same dissolution process caused the battery to
prematurely break down.
The ORNL team overcame these
barriers by first synthesizing a never-before-seen class of sulfur-rich
materials that conduct ions as well as the lithium metal oxides conventionally
used in the battery's cathode. Liang's team then combined the new sulfur-rich
cathode and a lithium anode with a solid electrolyte material, also developed
at ORNL, to create an energy-dense, all-solid battery.
"This game-changing shift from
liquid to solid electrolytes eliminates the problem of sulfur dissolution and
enables us to deliver on the promise of lithium-sulfur batteries," Liang
says. "Our battery design has real potential to reduce cost, increase
energy density and improve safety compared with existing lithium-ion
technologies."
The new ionically conductive cathode
enabled the ORNL battery to maintain a capacity of 1200 milliamp-hours (mAh)
per gram after 300 charge-discharge cycles at 60 C. For comparison, a
traditional lithium-ion battery cathode has an average capacity between 140 to
170 mAh/g. Because lithium-sulfur batteries deliver about half the voltage of
lithium-ion versions, this eight-fold increase in capacity demonstrated in the
ORNL battery cathode translates into four times the gravimetric energy density
of lithium-ion technologies, explains Liang.
The team's all-solid design also
increases battery safety by eliminating flammable liquid electrolytes that can
react with lithium metal. Chief among the ORNL battery's other advantages is
its use of elemental sulfur, a plentiful industrial byproduct of petroleum
processing.
"Sulfur is practically
free," Liang says. "Not only does sulfur store much more energy than
the transition metal compounds used in lithium-ion battery cathodes, but a
lithium-sulfur device could help recycle a waste product into a useful
technology."
Although the team's new battery is
still in the demonstration stage, Liang and his colleagues hope to see their
research move quickly from the laboratory into commercial applications. A
patent on the team's design is pending.
"This project represents a
synergy between basic science and applied research," Liang says. "We
used fundamental research to understand a scientific phenomenon, identified the
problem and then created the right material to solve that problem, which led to
the success of a device with real-world applications."
Source: Oak
Ridge National Laboratory
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