Use of Microwave-Assisted Deep Eutectic Solvents to Recycle Lithium Manganese Oxide from Li-Ion Batteries

Xu, Zhiwen; Shao, Huaishuang; Zhao, Qinxin; Liang, Zhiyuan

doi:10.1007/s11837-021-04641-x

Cited by 31 publications

(20 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[18] Additionally, an extraction yield for any target metal (Co, Ni, Mn) higher than 90 % was attained after only 4 h, and a maximum extraction yield close to 100, 93, and 94 % for Co, Ni, and Mn, respectively, was reached after 6 h. To date the highest extraction yield was reported for Co (100 � 3 %) using ethylene glycol:choline chloride (EG:CC) DES, [5,7,8,10,12] almost equal to that obtained using DES formulated using organic acid as hydrogen bond donor. [10,26] To evaluate whether the dissolution of metals was influenced by unknown species contained in the real waste LIBs black mass, a leaching test with duration of 24 h was performed with DESTT by employing commercial NMC111 (LiNi 1/3 Mn 1/3 Co 1/ 3 O 2 ) and NiO. Extraction yields close to those attained with the black mass were found (Figure 1d), excluding that unknown species from the black mass could have influenced metals dissolution.…”

Section: Resultsmentioning

confidence: 99%

Decomposition of Deep Eutectic Solvent Aids Metals Extraction in Lithium‐Ion Batteries Recycling

et al. 2022

View full text Add to dashboard Cite

The application of deep eutectic solvents (DESs) to dissolve metal oxides in lithium‐ion batteries (LIBs) recycling represents a green technological alternative to the mineral acids employed in hydrometallurgical recycling processes. However, DESs are much more expensive than mineral acids and must be reused to ensure economic feasibility of LIB recycling. To evaluate DES reusability, the role of the choline chloride‐ethylene glycol DES decomposition products on metal oxides dissolution was investigated. The temperatures generally applied to carry on this DES leaching induced the formation of decomposition products that ultimately improved the ability to dissolve LIB metal oxides. The characterization of DES decomposition products revealed that the improved metal dissolution was mainly determined by the formation of Cl3−, which was proposed to play a pivotal role in the oxidative dissolution of LIB metal oxides.

show abstract

Section: Resultsmentioning

confidence: 99%

Decomposition of Deep Eutectic Solvent Aids Metals Extraction in Lithium‐Ion Batteries Recycling

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Very recently, microwave-assisted treatment was employed to enhance the leaching efficiency using choline chloride-oxalic acid (ChCl-OA). [79] The report showed that the leaching efficiencies of both Li and Mn ions reached 99% and 96%, respectively, with only 15 min of microwave heating at 75 C. Although the result , with concentrations of 9.9 Â 10 3 ppm (red line), 7.9 Â 10 3 ppm (dark blue line), 6.6 Â 10 3 ppm (orange line), 4.9 Â 10 3 ppm (yellow line), 3.9 Â 10 3 ppm (light blue line), 3.0 Â 10 3 ppm (dark green line), 2.0 Â 10 3 ppm (gray line), 1.0 Â 103 ppm (light green line), and 0.5 Â 10 3 ppm (purple line). Adapted with permission.…”

Section: Des A)mentioning

confidence: 99%

Deep Eutectic Solvents: Green Approach for Cathode Recycling of Li‐Ion Batteries

Padwal

Pham

Jadhav

et al. 2021

Adv Energy and Sustain Res

View full text Add to dashboard Cite

Lithium-ion batteries (LIBs) are highvoltage, high-energy, and high-power density energy storage devices with long cycle life, therefore intensively applied in full and hybrid electric vehicles, portable electronic devices (computers, mobile phones, and tablet), and renewable (solar and wind) sector. [1,2] Typically, LIBs for such applications with estimated lifetime of around 3-10 years generate a vast amount of waste at their end-of-life. [3,4] It is estimated that over 11 million tonnes of spent LIBs will be discarded through to 2030, and only less than 5% of them are being recycled. [4] Moreover, due to rapidly increasing demand of LIBs, the price of crucial element resources (Li, Ni, and Co) is also significantly increasing. In contrast, the health and environmental concerns may arise in the event of large, accumulated quantities of cobalt and lithium metals, which typically constitutes up to 20 and 7 wt%, respectively, of LIB cathodes, as well as toxic and flammable electrolytes (e.g., lithium hexafluorophosphate, LiPF 6 ). [3][4][5] Therefore, efficient recovery of such raw materials in spent LIBs is extremely crucial.At present, LIBs are recycled commercially using well-known processes such as pyrometallurgy, hydrometallurgy, and direct recycling. [4] However, these processes do not extract the maximum value from their feedstock. For instance, pyrometallurgy, or smelting operate at very high temperature (over 1100 C), which eliminates several materials (carbon anode, plastic separator, and electrolyte solvents) through vaporization (electrolyte), combustion, and melting. The final product is a mixed alloy of cobalt, nickel, and copper. The concept of direct recycling is simple: keep the cathode crystal structure intact. The definition of direct recycling is the recovery, regeneration, and reuse of battery components directly without breaking down the chemical structure. It has also been called direct cathode recycling and cathode-to-cathode recycling. By recovering cathode material, several energy-intensive and costly processing steps can be avoided. Not only does recovery of more materials offer potential additional revenues, but also costs and other impacts from waste treatment can be avoided. Advantages include low temperatures and low energy consumption, and the avoidance of most impacts from virgin material production.

show abstract

“…In addition, with the assistance of microwave, the oxaline could efficiently recycle both Li and Mn ions from spent LIBs with a high extraction efficiency of 96% at only 75 °C with a leaching time of 15 min. 212 Additionally, Schiavi et al (2021) 213 focused on improving the selectivity of the DESs-based solvent extraction process towards the target metals (Co, Mn) over the impurities (Fe, Al and Cu). They developed a novel solvometallurgical process containing two successive DES leaching stages conducted at different temperatures (as shown in the flow diagram in Fig.…”

Section: Current Applications Of Des For Metal Recovery and Separatio...mentioning

confidence: 99%

“…35,36 In addition, with the assistance of microwave, the oxaline could efficiently recycle both Li and Mn ions from spent LIBs with a high extraction efficiency of 96% at only 75 °C with a leaching time of 15 min. 212 Furthermore, green leaching processes using DESs were approached to selective extraction of various metal ions from other e-waste, including end-of-life permanent magnets, 130,214 lamp phosphor waste, 215 and printed circuit boards (PCB). 96,118 Specifically, the guanidine hydrochloride-lactic acid (GUC-LAC) combined DES was screened from nine kinds of guanidine-based DESs as the best leachant to selectively extract the rare earth elements, neodymium (Nd), from the end-of-life permanent magnets with a high separation factor (>1300) between Nd and Fe through a simple selective dissolution step followed by precipitation process with oxalic acid.…”

Section: E-wastementioning

confidence: 99%

Status and advances of deep eutectic solvents for metal separation and recovery

et al. 2022

View full text Add to dashboard Cite

show abstract

Use of Microwave-Assisted Deep Eutectic Solvents to Recycle Lithium Manganese Oxide from Li-Ion Batteries

Cited by 31 publications

References 24 publications

Decomposition of Deep Eutectic Solvent Aids Metals Extraction in Lithium‐Ion Batteries Recycling

Decomposition of Deep Eutectic Solvent Aids Metals Extraction in Lithium‐Ion Batteries Recycling

Deep Eutectic Solvents: Green Approach for Cathode Recycling of Li‐Ion Batteries

Status and advances of deep eutectic solvents for metal separation and recovery

Contact Info

Product

Resources

About