The Role of Critical Raw Materials for Novel Strategies in Sustainable Secondary Batteries

Abstract: Energy storage technology is destined to play a central role to pave the way for a sustainable society. Although lithium‐based technology has covered the majority of energy storage necessities until now, the development of safe, clean, and recyclable technology to future transport sector, breakthroughs in materials and methods involving sustainable resources are crucial. In addition, materials, synthetic processes and final devices should be properly selected to contribute to the development of a sustainable e… Show more

“…The LCA study of Pell and Lindsay 54 quantified the GWP for ASB production in comparison to three commercial LIB chemistries (NMC 811, LFP, lithium-iron-manganese-phosphate). The oxide ASB with NMC 811 shows the lowest GWP with 58 kg CO 2 equivalents per kW per h while the LIB with LPF shows the highest GWP with 78 kg CO 2 equivalents per kW per h. Salado et al 55 provided a general overview of different battery types, followed by an analysis of critical raw materials currently used. They also focused on the more efficient, safer, and environmentally friendly next-generation batteries (ASBs, metal–air batteries, metal-sulfur batteries) and the use of metal–organic frameworks (MOFs) to achieve this.…”

Oxide ceramic electrolytes for all-solid-state lithium batteries – cost-cutting cell design and environmental impact

“…The LCA study of Pell and Lindsay 54 quantified the GWP for ASB production in comparison to three commercial LIB chemistries (NMC 811, LFP, lithium-iron-manganese-phosphate). The oxide ASB with NMC 811 shows the lowest GWP with 58 kg CO 2 equivalents per kW per h while the LIB with LPF shows the highest GWP with 78 kg CO 2 equivalents per kW per h. Salado et al 55 provided a general overview of different battery types, followed by an analysis of critical raw materials currently used. They also focused on the more efficient, safer, and environmentally friendly next-generation batteries (ASBs, metal–air batteries, metal-sulfur batteries) and the use of metal–organic frameworks (MOFs) to achieve this.…”

Oxide ceramic electrolytes for all-solid-state lithium batteries – cost-cutting cell design and environmental impact

Lithium‐Ion Batteries

Leaching valuable metals from spent lithium-ion batteries using the reducing agent methanol