November 22, 2024

New Material Derived From Trees Could Pave Way for Better, Safer Batteries

A product stemmed from trees might possibly replace liquid electrolytes in next-generation batteries.

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In pursuit of batteries that deliver more power and run more safely, scientists are working to replace the liquids typically utilized in todays lithium ion batteries with strong materials. Now, a research study group from Brown University and the University of Maryland has actually developed a new product for usage in solid-state batteries thats originated from a not likely source: trees.
In research published in the journal Nature, the team demonstrates a solid ion conductor that integrates copper with cellulose nanofibrils– polymer tubes originated from wood. The paper-thin material has an ion conductivity that is 10 to 100 times much better than other polymer ion conductors, the researchers say. It could be used as either a strong battery electrolyte or as an ion-conducting binder for the cathode of an all-solid-state battery.
A material obtained from trees might potentially replace liquid electrolytes in next-generation batteries. Credit: Hu laboratory/ University of Maryland.
” By including copper with one-dimensional cellulose nanofibrils, we demonstrated that the typically ion-insulating cellulose provides a speedier lithium-ion transport within the polymer chains,” said Liangbing Hu, a teacher in the University of Marylands Department of Materials Science and Engineering. “In fact, we found this ion conductor accomplished a record high ionic conductivity among all strong polymer electrolytes.”.
The work was a collaboration between Hus laboratory and the laboratory of Yue Qi, a professor at Browns School of Engineering.
Todays lithium ion batteries, which are extensively used in everything from cellphones to vehicles, have electrolytes made from lithium salt dissolved in a liquid organic solvent. The electrolytes job is to carry out lithium ions between a batterys cathode and anode. Liquid electrolytes work pretty well, but they have some downsides. At high currents, small filaments of lithium metal, called dendrites, can form in the electrolyte leading to short circuits. In addition, liquid electrolytes are made with flammable and hazardous chemicals, which can catch fire.
Strong electrolytes have the possible to prevent dendrite penetration and can be made from non-flammable materials. Most of the strong electrolytes investigated up until now are ceramic products, which are great at performing ions but theyre also thick, breakable and rigid. Stresses during manufacturing along with discharging and charging can result in cracks and breaks.
The product presented in this research study, nevertheless, is thin and versatile, practically like a sheet of paper. And its ion conductivity is on par with ceramics.
Qi and Qisheng Wu, a senior research partner at Brown, carried out computer system simulations of the microscopic structure of the copper-cellulose material to comprehend why it is able to perform ions so well. The modeling research study revealed that the copper increases the space between cellulose polymer chains, which typically exist in firmly packed bundles. The broadened spacing develops what quantity to ion superhighways through which lithium ions can zip by relatively unobstructed.
” The lithium ions relocate this organic strong electrolyte through mechanisms that we normally discovered in inorganic ceramics, enabling the record high ion conductivity,” Qi said. “Using products nature supplies will reduce the total effect of battery manufacture to our environment.”.
In addition to working as a solid electrolyte, the new material can likewise function as a cathode binder for a solid-state battery. In order to match the capacity of anodes, cathodes require to be significantly thicker. That thickness, however, can compromise ion conduction, minimizing efficiency. In order for thicker cathodes to work, they require to be encased in an ion-conducting binder. Using their brand-new material as a binder, the group showed what they think to be one of the thickest practical cathodes ever reported.
The scientists are confident that the new product might be a step towards bringing solid state battery technology to the mass market.
Recommendation: “Copper-coordinated cellulose ion conductors for solid-state batteries” by Chunpeng Yang, Qisheng Wu, Weiqi Xie, Xin Zhang, Alexandra Brozena, Jin Zheng, Mounesha N. Garaga, Byung Hee Ko, Yimin Mao, Shuaiming He, Yue Gao, Pengbo Wang, Madhusudan Tyagi, Feng Jiao, Robert Briber, Paul Albertus, Chunsheng Wang, Steven Greenbaum, Yan-Yan Hu, Akira Isogai, Martin Winter, Kang Xu, Yue Qi and Liangbing Hu, 20 October 2021, Nature.DOI: 10.1038/ s41586-021-03885-6.
The research at Brown University was supported by the National Science Foundation (DMR-2054438).

The paper-thin material has an ion conductivity that is 10 to 100 times better than other polymer ion conductors, the scientists say. Todays lithium ion batteries, which are widely used in whatever from cellular phones to cars, have actually electrolytes made from lithium salt liquified in a liquid organic solvent. The electrolytes job is to conduct lithium ions in between a batterys cathode and anode. Most of the solid electrolytes examined so far are ceramic products, which are fantastic at carrying out ions however theyre also thick, stiff and breakable. The expanded spacing creates what quantity to ion superhighways through which lithium ions can zip by fairly unobstructed.