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Researchers in China use citric acid for efficient recycling of NCM Li-ion batteries; Fischer lactonization

Researchers in China have developed a simple, highly efficient, inexpensive, and environmentally friendly processfor the sustainable recycling of depleted lithium-ion batteries (LIBs). No chemicals beyond citric acid need to be added to leach out and separate more than 99% of the lithium, nickel, cobalt, and manganese metals contained in NCM batteries. The resulting recycled material can be directly converted into NCM electrodes.

A paper on the work is published in the journal Angewandte Chemie.

Most recycling processes suffer from high energy usage, high emissions, and limited or low-quality recovered material. Or they require very large amounts of chemicals, are complicated and expensive, and produce toxic gases and run-off. Leaching with biocompatible acids like citric acid is one alternative to these processes. However, conventional processes (chelation-gel process) require a significant excess of the acid, and the pH value must constantly be adjusted with ammonia—complicated and not very environmentally friendly.

A team at China University of Mining and Technology (Beijing), Fuzhou University, Beijing University of Chemical Technology, and Tsinghua University, Shenzhen (China) led by Guangmin Zhou and Ruiping Liu has now developed a novel citric-acid-based method for the leeching, separation, and reclamation of metals from NCM cathodes. NCM is a mixed oxide containing nickel, cobalt, and manganese in a lamellar structure. Lithium ions are enclosed between the layers.

IMG_1181

Zhou et al.


Instead of leeching with an excess of citric acid as in conventional methods, the team used a relatively small amount. Because of this, only two of the three acid groups in the citric acid dissociate. The released protons break up the lithium-oxygen bonds, releasing lithium ions from the NCM into the solution. Bonds between the other metal ions and the oxygen ions are also broken.

Nickel, cobalt, and manganese enter the solution, where they are bound into stable complexes by the citric acid anions. The third acid group of the citric acid then reacts with the hydroxyl group on the same molecule. A ring closure occurs in an intramolecular esterification (Fischer lactonization) reaction.

This facilitates the reaction of the intermediates with each other to make a polyester, which gels into solid particles that can easily be separated out. Energy consumption and CO2 emissions are significantly less than in conventional hydrometallurgical recycling processes.

The gel can subsequently be heated to burn off the organic fragment. This results in a new NCM lamellar framework with included lithium ions, which can be used as a high-quality electrode material.

Resources

  • M. Zhou, J. Shen, Y. Zuo, R. Liu, J. Zhao, G. Zhou, Angew. Chem. Int. Ed. 2024, e202414484. doi: 10.1002/anie.202414484

Comments

mahonj

Lower cost and lower energy usage for battery recycling has to be a good thing.
It will be a lot easier to mine Cobalt in old batteries than the Congo.

SJC

Even if they can just recover the cathodes this would be a plus.

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