Branchlike metallic filaments can sap the power of solid-state lithium batteries. A new study explains how they form and how to divert them.
From: MIT
News Office
By David L. Chandler
November 18, 2022 -- A discovery by MIT researchers could finally unlock
the door to the design of a new kind of rechargeable lithium battery that is
more lightweight, compact, and safe than current versions, and that has been
pursued by labs around the world for years.
The key to this potential leap in battery technology is replacing the
liquid electrolyte that sits between the positive and negative electrodes with
a much thinner, lighter layer of solid ceramic material, and replacing one of
the electrodes with solid lithium metal. This would greatly reduce the overall
size and weight of the battery and remove the safety risk associated with
liquid electrolytes, which are flammable. But that quest has been beset with
one big problem: dendrites.
Dendrites, whose name comes from the Latin for branches, are projections
of metal that can build up on the lithium surface and penetrate into the solid
electrolyte, eventually crossing from one electrode to the other and shorting
out the battery cell. Researchers haven’t been able to agree on what gives rise
to these metal filaments, nor has there been much progress on how to prevent
them and thus make lightweight solid-state batteries a practical option.
The new research, being published today in the journal Joule in
a paper by MIT Professor Yet-Ming Chiang, graduate student Cole Fincher, and
five others at MIT and Brown University, seems to resolve the question of what
causes dendrite formation. It also shows how dendrites can be prevented from
crossing through the electrolyte.
Chiang says in the group’s earlier work, they made a “surprising and
unexpected” finding, which was that the hard, solid electrolyte material used
for a solid-state battery can be penetrated by lithium, which is a very soft
metal, during the process of charging and discharging the battery, as ions of
lithium move between the two sides.
This shuttling back and forth of ions causes the volume of the electrodes
to change. That inevitably causes stresses in the solid electrolyte, which has
to remain fully in contact with both of the electrodes that it is sandwiched
between. “To deposit this metal, there has to be an expansion of the volume
because you’re adding new mass,” Chiang says. “So, there’s an increase in
volume on the side of the cell where the lithium is being deposited. And if
there are even microscopic flaws present, this will generate a pressure on
those flaws that can cause cracking.”
Those stresses, the team has now shown, cause the cracks that allow
dendrites to form. The solution to the problem turns out to be more stress,
applied in just the right direction and with the right amount of force.
While previously, some researchers thought that dendrites formed by a
purely electrochemical process, rather than a mechanical one, the team’s experiments
demonstrate that it is mechanical stresses that cause the problem.
The process of dendrite formation normally takes place deep within the
opaque materials of the battery cell and cannot be observed directly, so
Fincher developed a way of making thin cells using a transparent electrolyte,
allowing the whole process to be directly seen and recorded. “You can see what
happens when you put a compression on the system, and you can see whether or
not the dendrites behave in a way that's commensurate with a corrosion process
or a fracture process,” he says.
The team demonstrated that they could directly manipulate the growth of
dendrites simply by applying and releasing pressure, causing the dendrites to
zig and zag in perfect alignment with the direction of the force.
Applying mechanical stresses to the solid electrolyte doesn’t eliminate
the formation of dendrites, but it does control the direction of their growth.
This means they can be directed to remain parallel to the two electrodes and
prevented from ever crossing to the other side, and thus rendered harmless.
In their tests, the researchers used pressure induced by bending the
material, which was formed into a beam with a weight at one end. But they say
that in practice, there could be many different ways of producing the needed
stress. For example, the electrolyte could be made with two layers of material
that have different amounts of thermal expansion, so that there is an inherent
bending of the material, as is done in some thermostats.
Another approach would be to “dope” the material with atoms that would
become embedded in it, distorting it and leaving it in a permanently stressed
state. This is the same method used to produce the super-hard glass used in the
screens of smart phones and tablets, Chiang explains. And the amount of
pressure needed is not extreme: The experiments showed that pressures of 150 to
200 megapascals were sufficient to stop the dendrites from crossing the
electrolyte.
The required pressure is “commensurate with stresses that are commonly
induced in commercial film growth processes and many other manufacturing
processes,” so should not be difficult to implement in practice, Fincher adds.
In fact, a different kind of stress, called stack pressure, is often
applied to battery cells, by essentially squishing the material in the
direction perpendicular to the battery’s plates — somewhat like compressing a
sandwich by putting a weight on top of it. It was thought that this might help
prevent the layers from separating. But the experiments have now demonstrated
that pressure in that direction actually exacerbates dendrite formation. “We
showed that this type of stack pressure actually accelerates dendrite-induced
failure,” Fincher says.
What is needed instead is pressure along the plane of the plates, as if
the sandwich were being squeezed from the sides. “What we have shown in this
work is that when you apply a compressive force you can force the dendrites to
travel in the direction of the compression,” Fincher says, and if that
direction is along the plane of the plates, the dendrites “will never get to
the other side.”
That could finally make it practical to produce batteries using solid
electrolyte and metallic lithium electrodes. Not only would these pack more
energy into a given volume and weight, but they would eliminate the need for
liquid electrolytes, which are flammable materials.
Having demonstrated the basic principles involved, the team’s next step
will be to try to apply these to the creation of a functional prototype
battery, Chiang says, and then to figure out exactly what manufacturing
processes would be needed to produce such batteries in quantity. Though they
have filed for a patent, the researchers don’t plan to commercialize the system
themselves, he says, as there are already companies working on the development
of solid-state batteries. “I would say this is an understanding of failure
modes in solid-state batteries that we believe the industry needs to be aware
of and try to use in designing better products,” he says.
The research team included Christos Athanasiou and Brian Sheldon at Brown
University, and Colin Gilgenbach, Michael Wang, and W. Craig Carter at MIT. The
work was supported by the U.S. National Science Foundation, the U.S. Department
of Defense, the U.S. Defense Advanced Research Projects Agency, and the U.S.
Department of Energy.
No comments:
Post a Comment