Thermal Analysis Techniques for Technical Ceramics and Glasses

“…Solid-state sintering, a traditional method commonly used for cathode material preparation, 194 is a method of bonding and densification of particles during heating. 195 To optimize the properties, a high density of the material achieved by powder processing is usually required. 195 Given the degradation mechanism of the cathode in spent LIBs, solid-state sintering is usually used in the direct recycling of cathode materials because it allows the regrowth of particles for possible repairing of those degraded defects.…”

“…195 To optimize the properties, a high density of the material achieved by powder processing is usually required. 195 Given the degradation mechanism of the cathode in spent LIBs, solid-state sintering is usually used in the direct recycling of cathode materials because it allows the regrowth of particles for possible repairing of those degraded defects. In 2015, Nie et al 196 reported an efficient recycling process for the direct recycling of spent LCO by solid-state sintering, which varied from the conventional recycling methods.…”

Toward Direct Regeneration of Spent Lithium-Ion Batteries: A Next-Generation Recycling Method

“…Solid-state sintering, a traditional method commonly used for cathode material preparation, 194 is a method of bonding and densification of particles during heating. 195 To optimize the properties, a high density of the material achieved by powder processing is usually required. 195 Given the degradation mechanism of the cathode in spent LIBs, solid-state sintering is usually used in the direct recycling of cathode materials because it allows the regrowth of particles for possible repairing of those degraded defects.…”

“…195 To optimize the properties, a high density of the material achieved by powder processing is usually required. 195 Given the degradation mechanism of the cathode in spent LIBs, solid-state sintering is usually used in the direct recycling of cathode materials because it allows the regrowth of particles for possible repairing of those degraded defects. In 2015, Nie et al 196 reported an efficient recycling process for the direct recycling of spent LCO by solid-state sintering, which varied from the conventional recycling methods.…”

Toward Direct Regeneration of Spent Lithium-Ion Batteries: A Next-Generation Recycling Method

“…Gas foaming can be combined with sintering to prepare glass/ceramic dual-porosity scaffolds [187,[202][203][204][205][206][207][208][209][210][211][212] in two ways: 1) Sol-gel foaming, where a foaming step is added during the sol-gel synthesis of glass to create a macroporous glass scaffold, and the resulting scaffold is later subjected to sintering to create micropores. [211] 2) Gel-cast foaming, where a foaming agent is added to a slurry of glass or ceramic powder, is then combined with organic monomers along with dispersants and binders. Gelation is induced by in situ polymerization followed by sintering.…”

“…Here, the macropores arise from the foam, and micropores are created from the sintering process. [211] For example, ß-TCP scaffolds with triple porosity have been prepared by sol-gel foaming using Pluronic F127 as a surfactant. The scaffolds contained macropores of diameter 200-500 μm caused by foaming, micropores of diameter 0.5-5 μm caused by sintering, and nanopores of diameter 3-10 nm created by the removal of the surfactant (Figure 3G,H).…”

“…Here, the macropores arise from the foam, and micropores are created from the sintering process. [ 211 ]…”

Glass, Ceramic, Polymeric, and Composite Scaffolds with Multiscale Porosity for Bone Tissue Engineering

The Thermal Behavior of Cordierite-Based Ceramic with the Substitution of Treated Flue Gas Desulfurization Sludge in the Non-stoichiometric Cordierite Composition