Lithium-Ion and Next-Generation Batteries Recycling
The progressive expansion of electromobility will lead to an increasing demand for lithium-ion batteries (LIBs) in the future and thus inevitably to a drastically increased demand for raw materials for battery materials. The recycling and reuse of the individual components therefore serves as an imp...
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MDPI - Multidisciplinary Digital Publishing Institute
2026
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| description | The progressive expansion of electromobility will lead to an increasing demand for lithium-ion batteries (LIBs) in the future and thus inevitably to a drastically increased demand for raw materials for battery materials. The recycling and reuse of the individual components therefore serves as an important link in achieving a circular economy, whereby the dependence on geographically unevenly distributed elements and the associated costs can be reduced and the sustainability within the value chain improved. Lithium-ion batteries (LIBs) and upcoming cell chemistries like sodium-ion or lithium–sulfur batteries are and will be an integral part of our modern way of life, particularly in portable electronic devices and the emerging field of electric mobility. Ongoing research in the field, with the overarching aim of achieving higher energy densities and enabling lower material costs, has led to the continuous development of new cell chemistries specifically adapted to different requirements. The resulting high complexity of battery systems in combination with varying battery lifetimes leads to a heterogeneous flow of used end-of-life cells. In view of this, the establishment of universal, flexible, and robust recycling processes remains a major challenge, which is why it is crucial to thoroughly analyze and optimize the current state of the art and adapt it to future types and cell chemistries. |
| format | Online |
| id | doab-20.500.12854ir-175184 |
| institution | Directory of Open Access Books |
| language | eng |
| publishDate | 2026 |
| publishDateRange | 2026 |
| publishDateSort | 2026 |
| publisher | MDPI - Multidisciplinary Digital Publishing Institute |
| publisherStr | MDPI - Multidisciplinary Digital Publishing Institute |
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| spelling | doab-20.500.12854ir-1751842026-04-16T19:23:00Z Lithium-Ion and Next-Generation Batteries Recycling Nowak, Sascha Circular economy Li-ion battery Recovery Recycling Reuse Lithium-ion batteries Spent electrolyte Analytics Gas chromatography Impurities Distillation Rectification Lithium-ion battery Electric vehicles Automated battery disassembly Dismantling challenges Battery recycling Battery product structure Battery process structure Battery passport Dihydrolevoglucosenone Pyrolysis Tof-SIMS PVDF Spent LIBs Electric vehicle Battery Battery waste Battery waste recycling Battery waste recycling policies and regulation Black mass Froth flotation Graphite Refractory industry Open-loop recycling Critical raw materials Spent Direct liquid phase exfoliation Graphene Lithium Monte Carlo simulation Policy Flash Joule heating Spent graphite Porous expanded graphite Anode High-value reutilization Lithium-ion battery recycling Copper foil recovery Thermal decoating Aqueous delamination Anode recycling thema EDItEUR::G Reference, Information and Interdisciplinary subjects::GP Research and information: general The progressive expansion of electromobility will lead to an increasing demand for lithium-ion batteries (LIBs) in the future and thus inevitably to a drastically increased demand for raw materials for battery materials. The recycling and reuse of the individual components therefore serves as an important link in achieving a circular economy, whereby the dependence on geographically unevenly distributed elements and the associated costs can be reduced and the sustainability within the value chain improved. Lithium-ion batteries (LIBs) and upcoming cell chemistries like sodium-ion or lithium–sulfur batteries are and will be an integral part of our modern way of life, particularly in portable electronic devices and the emerging field of electric mobility. Ongoing research in the field, with the overarching aim of achieving higher energy densities and enabling lower material costs, has led to the continuous development of new cell chemistries specifically adapted to different requirements. The resulting high complexity of battery systems in combination with varying battery lifetimes leads to a heterogeneous flow of used end-of-life cells. In view of this, the establishment of universal, flexible, and robust recycling processes remains a major challenge, which is why it is crucial to thoroughly analyze and optimize the current state of the art and adapt it to future types and cell chemistries. 2026-04-16T19:22:54Z 2026-04-16T19:22:54Z 2026 book ONIX_20260416T142754_9783725862689_39 9783725862689 9783725862696 https://directory.doabooks.org/handle/20.500.12854/175184 eng application/octet-stream Attribution 4.0 International https://mdpi.com/books/ https://mdpi.com/books/pdfview/book/12096 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-7258-6269-6 10.3390/books978-3-7258-6269-6 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783725862689 9783725862696 246 CH open access |
| spellingShingle | Circular economy Li-ion battery Recovery Recycling Reuse Lithium-ion batteries Spent electrolyte Analytics Gas chromatography Impurities Distillation Rectification Lithium-ion battery Electric vehicles Automated battery disassembly Dismantling challenges Battery recycling Battery product structure Battery process structure Battery passport Dihydrolevoglucosenone Pyrolysis Tof-SIMS PVDF Spent LIBs Electric vehicle Battery Battery waste Battery waste recycling Battery waste recycling policies and regulation Black mass Froth flotation Graphite Refractory industry Open-loop recycling Critical raw materials Spent Direct liquid phase exfoliation Graphene Lithium Monte Carlo simulation Policy Flash Joule heating Spent graphite Porous expanded graphite Anode High-value reutilization Lithium-ion battery recycling Copper foil recovery Thermal decoating Aqueous delamination Anode recycling thema EDItEUR::G Reference, Information and Interdisciplinary subjects::GP Research and information: general Lithium-Ion and Next-Generation Batteries Recycling |
| title | Lithium-Ion and Next-Generation Batteries Recycling |
| title_full | Lithium-Ion and Next-Generation Batteries Recycling |
| title_fullStr | Lithium-Ion and Next-Generation Batteries Recycling |
| title_full_unstemmed | Lithium-Ion and Next-Generation Batteries Recycling |
| title_short | Lithium-Ion and Next-Generation Batteries Recycling |
| title_sort | lithium ion and next generation batteries recycling |
| topic | Circular economy Li-ion battery Recovery Recycling Reuse Lithium-ion batteries Spent electrolyte Analytics Gas chromatography Impurities Distillation Rectification Lithium-ion battery Electric vehicles Automated battery disassembly Dismantling challenges Battery recycling Battery product structure Battery process structure Battery passport Dihydrolevoglucosenone Pyrolysis Tof-SIMS PVDF Spent LIBs Electric vehicle Battery Battery waste Battery waste recycling Battery waste recycling policies and regulation Black mass Froth flotation Graphite Refractory industry Open-loop recycling Critical raw materials Spent Direct liquid phase exfoliation Graphene Lithium Monte Carlo simulation Policy Flash Joule heating Spent graphite Porous expanded graphite Anode High-value reutilization Lithium-ion battery recycling Copper foil recovery Thermal decoating Aqueous delamination Anode recycling thema EDItEUR::G Reference, Information and Interdisciplinary subjects::GP Research and information: general |
| topic_facet | Circular economy Li-ion battery Recovery Recycling Reuse Lithium-ion batteries Spent electrolyte Analytics Gas chromatography Impurities Distillation Rectification Lithium-ion battery Electric vehicles Automated battery disassembly Dismantling challenges Battery recycling Battery product structure Battery process structure Battery passport Dihydrolevoglucosenone Pyrolysis Tof-SIMS PVDF Spent LIBs Electric vehicle Battery Battery waste Battery waste recycling Battery waste recycling policies and regulation Black mass Froth flotation Graphite Refractory industry Open-loop recycling Critical raw materials Spent Direct liquid phase exfoliation Graphene Lithium Monte Carlo simulation Policy Flash Joule heating Spent graphite Porous expanded graphite Anode High-value reutilization Lithium-ion battery recycling Copper foil recovery Thermal decoating Aqueous delamination Anode recycling thema EDItEUR::G Reference, Information and Interdisciplinary subjects::GP Research and information: general |
| url | ONIX_20260416T142754_9783725862689_39 |