Researchers prepare an experimental flow battery electrolyte that has shown long life in the laboratory setting. Credit: Andrea Starr | Pacific Northwest National Laboratory)
A
common food and medicine additive has shown it can boost the capacity and
longevity of a next-generation flow battery design in a record-setting
experiment.
A research team from the Department of
Energy's Pacific Northwest National Laboratory reports that the flow battery, a design optimized for electrical grid energy
storage, maintained its capacity to store and release energy for more than a
year of continuous charge and discharge.
The study, just published in the journal Joule, details the first use of a dissolved simple
sugar called β-cyclodextrin, a
derivative of starch, to boost battery longevity and capacity. In a series of
experiments, the scientists optimized the ratio of chemicals in the system
until it achieved 60 percent more peak power.
Then, they cycled the battery over and
over for more than a year, only stopping the experiment when the plastic tubing
failed. During all that time, the flow battery barely lost any of its activity
to recharge. This is the first laboratory-scale flow battery experiment to report
more than a year of continuous use with minimal loss of capacity.
The β-cyclodextrin additive is also the first to speed the
electrochemical reaction that stores and then releases the flow battery energy,
in a process called homogeneous catalysis. This means the sugar does its work
while dissolved in solution, rather than as a solid applied to a surface.
Researchers prepare an experimental flow battery
electrolyte that has shown long life in the laboratory setting. Credit: Sara
Levine, Pacific Northwest National Laboratory
"This is a brand new approach
to developing flow battery electrolyte," said Wei Wang, a long-time PNNL
battery researcher and the principal investigator of the study. "We showed
that you can use a totally different type of catalyst designed to accelerate
the energy conversion. And further, because it is dissolved in the liquid
electrolyte it eliminates the possibility of a solid dislodging and fouling the
system."
What is a flow battery?
As their name suggests, flow
batteries consist of two chambers, each filled with a different liquid. The
batteries charge through an electrochemical reaction and store energy in
chemical bonds. When connected to an external circuit, they release that energy,
which can power electrical devices. Flow batteries differ from solid-state
batteries in that they have two external supply tanks of liquid constantly
circulating through them to supply the electrolyte, which is like the
"blood supply" for the system. The larger the electrolyte supply
tank, the more energy the flow battery can store.
If they are scaled up to the size
of a football field or more, flow batteries can serve as backup generators for
the electric grid. Flow batteries are one of the key pillars of a
decarbonization strategy to store energy from renewable energy resources. Their
advantage is that they can be built at any scale, from the lab-bench scale, as
in the PNNL study, to the size of a city block.
Why do we need new kinds of flow batteries?
Large-scale energy storage provides
a kind of insurance policy against disruption to our electrical grid.
When severe weather or high demand hobble the ability to supply
electricity to homes and businesses, energy stored in large-scale flow battery
facilities can help minimize disruption or restore service. The need for these
flow battery facilities is only expected to grow, as electricity generation
increasingly comes from renewable energy sources, such as wind, solar and
hydroelectric power. Intermittent power sources such as these require a place
to store energy until it's needed to meet consumer demand.
While there are many flow battery
designs and some commercial installations, existing commercial facilities rely
on mined minerals such as vanadium that are costly and difficult to obtain.
That's why research teams are seeking effective alternative technologies that
use more common materials that are easily synthesized, stable and non-toxic.
Flow battery researcher Ruozhu Feng poses with
ingredients for a long-lasting grid energy battery. Credit: Andrea Starr |
Pacific Northwest National Laboratory
"We cannot always dig the
Earth for new materials," said Imre Gyuk, director of energy storage research
at DOE's Office of Electricity. "We need to develop a sustainable approach
with chemicals that we can synthesize in large amounts—just like the
pharmaceutical and the food industries."
The work on flow batteries is part
of a large program at PNNL to develop and test new technologies for grid-scale
energy storage that will be accelerated with the opening of PNNL's Grid Storage Launchpad in 2024.
A benign 'sugar water' sweetens the pot for an effective flow battery
The PNNL research team that
developed this new battery design includes researchers with backgrounds in
organic and chemical synthesis. These skills came in handy when the team chose
to work with materials that had not been used for battery research, but which
are already produced for other industrial uses.
"We were looking for a simple
way to dissolve more fluorenol in our water-based electrolyte," said
Ruozhu Feng, the first author of the new study. "The β-cyclodextrin helped do that, modestly, but it's real
benefit was this surprising catalytic ability."
The researchers then worked with
co-author Sharon Hammes-Schiffer of Yale University, a leading authority on the
chemical reaction underlying the catalytic boost, to explain how it works.
As described in the research study,
the sugar additive accepts positively charged protons, which helps balance out
the movement of negative electrons as the battery discharges. The details are a
bit more complicated, but it's like the sugar sweetens the pot to allow the
other chemicals to complete their chemical dance.
The study is the next generation of
a PNNL-patented flow battery design first described in the journal Science in
2021. There, the researchers showed that another common chemical, called
fluorenone, is an effective flow battery
component. But that
initial breakthrough needed improvement because the process was slow compared
with commercialized flow battery technology. This new advance makes the battery
design a candidate for scale up, the researchers say.
At the same time, the research team
is working to further improve the system by experimenting with other compounds
that are similar to β-cyclodextrin but smaller. Like honey, β-cyclodextrin addition also makes the liquid thicker,
which is less than ideal for a flowing system. Nonetheless, the researchers
found its benefits outweighed its drawbacks.
Understanding the complex chemistry
happening inside the new flow battery design required the expertise of many
scientists, including Ying Chen, Xin Zhang, Peiyuan Gao, Ping Chen, Sebastian
Mergelsberg, Lirong Zhong, Aaron Hollas, Yangang Lian, Vijayakumar Murugesan,
Qian Huang, Eric Walter and Yuyan Shao of PNNL, and Benjamin J. G. Rousseau and
Hammes-Schiffer of Yale, in addition to Feng and Wang.
The research team has applied for U.S. patent protection for their new battery design.
by Pacific Northwest National
Laboratory
Source: Next-generation flow battery design sets records (techxplore.com)
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