05967nam 2201441z- 450 991063998830332120231214133602.03-0365-5926-4(CKB)5470000001633471(oapen)https://directory.doabooks.org/handle/20.500.12854/95821(EXLCZ)99547000000163347120202301d2022 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierNew Science Based Concepts for Increased Efficiency in Battery Recycling 2020BaselMDPI - Multidisciplinary Digital Publishing Institute20221 electronic resource (412 p.)3-0365-5925-6 Based on 19 high-quality articles, this Special Issue presents methods for further improving the currently achievable recycling rate, product quality in terms of focused elements, and approaches for the enhanced mobilization of lithium, graphite, and electrolyte components. In particular, the target of early-stage Li removal is a central point of various research approaches in the world, which has been reported, for example, under the names early-stage lithium recovery (ESLR process) with or without gaseous CO2 and supercritical CO2 leaching (COOL process). Furthermore, many more approaches are present in this Special Issue, ranging from robotic disassembly and the dismantling of Li‐ion batteries, or the optimization of various pyro‐ and hydrometallurgical as well as combined battery recycling processes for the treatment of conventional Li‐ion batteries, all the way to an evaluation of the recycling on an industrial level. In addition to the consideration of Li distribution in compounds of a Li2O-MgO-Al2O3-SiO2-CaO system, Li recovery from battery slags is also discussed. The development of suitable recycling strategies of six new battery systems, such as all-solid-state batteries, but also lithium–sulfur batteries, is also taken into account here. Some of the articles also discuss the fact that battery recycling processes do not have to produce end products such as high-purity battery materials, but that the aim should be to find an “entry point” into existing, proven large-scale industrial processes. Participants in this Special Issue originate from 18 research institutions from eight countries.Technology: general issuesbicsscHistory of engineering & technologybicsscMining technology & engineeringbicssclead-acid battery recyclingpyrite cinder treatmentlead bullionsulfide matteSO2 emissionspilot plantenvironmental technologieswaste treatmentrecyclingspent lithium-ion batteriesrecycling chainprocess stagesunit processesindustrial recycling technologiesmechanical treatmentslag cleaningcobaltnickelmanganeselithium-ion batterycircular economybatteriesreusedisassemblysafetylithium mineralslithium slag characterizationthermochemical modelingcritical raw materialssmeltinglithiumgraphitemechanical processingpyrometallurgythermal treatmentpyrolysishydrometallurgyprecipitationoxalic acidmixed oxalatebattery recyclinglithium-sulfur batteriesmetallurgical recyclingmetal recoveryrecycling efficiencylithium-ion batteriesall-solid-state batteriesslagleachingdry digestionfractionationtubular centrifugerotational speed controlparticle size analysislithium iron phosphateLFPcarbon blackdirect battery recyclingrecoverythermodynamic modelingengineered artificial minerals (EnAM)melt experimentsPXRDEPMAmanganese recoverysolvent extractionD2EHPAfactorial design of experimentslithium-ion batteries (LIBs)lithium removalphosphorous removalrecovery of valuable metalscarbonationlithium phase transformationautoclavesupercritical CO2X-ray absorption near edge structure (XANES)powder X-ray diffraction (PXRD)electron probe microanalysis (EPMA)lithium recyclinglithium batteriesblack massLIBmechanical recycling processesbattery generationsolid state batteriesrobotic disassemblyelectric vehicle batterytask plannerTechnology: general issuesHistory of engineering & technologyMining technology & engineeringFriedrich Berndedt307173Friedrich BerndothBOOK9910639988303321New Science Based Concepts for Increased Efficiency in Battery Recycling 20203015484UNINA