December 23, 2024

MIT Discovery Could Unlock a Safer and Lighter Lithium Battery

Solid-state lithium batteries are a type of rechargeable battery that uses a strong electrolyte instead of a liquid one. They offer several benefits over standard lithium-ion batteries, such as higher energy density, enhanced security, and better thermal stability.
Solid-state lithium batteries are impacted by the growth of branchlike metal filaments. A recent research study explores the development of these filaments and provides a solution to avoid them from forming, protecting battery power.
Massachusetts Institute of Technology scientists have made a development that could pave the method for the advancement of an advanced rechargeable lithium battery. This new design is expected to be more lightweight, compact, and more secure than existing designs.
The key to this possible leap in battery innovation is replacing the liquid electrolyte that sits between the favorable and negative electrodes with a much thinner, lighter layer of strong ceramic product, and replacing among the electrodes with solid lithium metal. This would considerably reduce the overall size and weight of the battery and get rid of the safety threat connected with liquid electrolytes, which are combustible. That quest has actually been beset with one big issue: dendrites.

Dendrites, whose name originates from the Latin for branches, are projections of metal that can build up on the lithium surface and permeate into the solid electrolyte, eventually crossing from one electrode to the other and shorting out the battery cell. Researchers have not had the ability to settle on what offers increase to these metal filaments, nor has there been much progress on how to avoid them and therefore make light-weight solid-state batteries a practical choice.
The brand-new research study, just recently released 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 solve the concern of what causes dendrite development. It likewise demonstrates how dendrites can be avoided from crossing through the electrolyte.
Chiang says in the groups earlier work, they made a “unforeseen and surprising” finding, which was that the hard, solid electrolyte material utilized for a solid-state battery can be permeated by lithium, which is a really soft metal, throughout the process of charging and releasing the battery, as ions of lithium relocation between the 2 sides.
That undoubtedly triggers stresses in the solid electrolyte, which has to remain totally in contact with both of the electrodes that it is sandwiched in between. “So, theres a boost in volume on the side of the cell where the lithium is being transferred.
Those stresses, the team has now revealed, trigger the cracks that enable dendrites to form. The solution to the problem turns out to be more stress, applied in simply the best instructions and with the correct amount of force.
While previously, some scientists believed that dendrites formed by a simply electrochemical procedure, instead of a mechanical one, the teams experiments demonstrate that it is mechanical stresses that trigger the problem.
The process of dendrite formation generally takes location deep within the opaque materials of the battery cell and can not be observed directly, so Fincher established a method of making thin cells utilizing a transparent electrolyte, permitting the entire process to be directly seen and tape-recorded. “You can see what takes place when you put a compression on the system, and you can see whether the dendrites behave in such a way thats commensurate with a corrosion process or a fracture procedure,” he states.
The group demonstrated that they could directly control the growth of dendrites merely by applying and launching pressure, causing the dendrites to zig and zag in ideal alignment with the direction of the force.
Using mechanical stresses to the strong electrolyte does not remove the formation of dendrites, but it does control the direction of their development. This means they can be directed to remain parallel to the 2 electrodes and prevented from ever crossing to the opposite, and therefore rendered safe.
In their tests, the researchers utilized pressure caused by bending the product, which was formed into a beam with a weight at one end. They state that in practice, there might be numerous different methods of producing the required stress. For instance, the electrolyte might be made with two layers of product that have different quantities of thermal expansion, so that there is an intrinsic bending of the product, as is carried out in some thermostats.
Another method would be to “dope” the material with atoms that would become ingrained in it, misshaping it and leaving it in a permanently stressed state. This is the exact same technique utilized to produce the super-hard glass used in the screens of tablets and smartphones, Chiang discusses. And the amount of pressure required is not severe: The experiments revealed that pressures of 150 to 200 megapascals sufficed to stop the dendrites from crossing the electrolyte.
The necessary pressure is “commensurate with tensions that are typically caused in business film growth procedures and lots of other production procedures,” so must not be hard to carry out in practice, Fincher adds.
In reality, a various sort of tension, called stack pressure, is often applied to battery cells, by essentially squishing the product in the instructions perpendicular to the batterys plates– somewhat like compressing a sandwich by putting a weight on top of it. It was believed that this might assist prevent the layers from separating. The experiments have actually now demonstrated that pressure in that instructions in fact worsens dendrite formation. “We showed that this kind of stack pressure in fact speeds up dendrite-induced failure,” Fincher states.
What is required rather is pressure along the plane of the plates, as if the sandwich were being squeezed from the sides. “What we have actually displayed in this work is that when you apply a compressive force you can require the dendrites to take a trip in the direction of the compression,” Fincher states, and if that instructions is along the aircraft of the plates, the dendrites “will never ever get to the other side.”
That could lastly make it useful to produce batteries utilizing solid electrolyte and metal lithium electrodes. Not just would these pack more energy into a given volume and weight, however they would eliminate the need for liquid electrolytes, which are combustible materials.
Having shown the standard concepts involved, the groups next step will be to try to apply these to the development of a practical prototype battery, Chiang states, and then to find out exactly what production procedures would be needed to produce such batteries in quantity. Though they have actually declared a patent, the scientists dont prepare to advertise the system themselves, he says, as there are already companies dealing with the development of solid-state batteries. “I would say this is an understanding of failure modes in solid-state batteries that our company believe the industry needs to be knowledgeable about and try to utilize in creating much better products,” he says.
Reference: “Controlling dendrite propagation in solid-state batteries with engineered tension” by Cole D. Fincher, Christos E. Athanasiou, Colin Gilgenbach, Michael Wang, Brian W. Sheldon, W. Craig Carter and Yet-Ming Chiang, 18 November 2022, Joule.DOI: 10.1016/ j.joule.2022.10.011.
The research study was funded 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.

The secret to this possible leap in battery innovation is replacing the liquid electrolyte that sits in between the unfavorable and positive electrodes with a much thinner, lighter layer of solid ceramic product, and changing one of the electrodes with solid lithium metal. A different kind of tension, called stack pressure, is typically used to battery cells, by essentially squishing the material in the direction perpendicular to the batterys plates– somewhat like compressing a sandwich by putting a weight on top of it. Having actually demonstrated the fundamental principles involved, the teams next action will be to try to use these to the creation of a functional prototype battery, Chiang says, and then to figure out exactly what manufacturing procedures would be required to produce such batteries in quantity. They have actually filed for a patent, the scientists dont plan to commercialize the system themselves, he states, as there are currently companies working on the advancement of solid-state batteries. “I would say this is an understanding of failure modes in solid-state batteries that we think the industry requires to be aware of and try to use in creating much better products,” he says.