材料科学
多孔性
复合材料
铸造
还原(数学)
铜
多孔介质
冶金
几何学
数学
作者
Jean Pascal Fandré,Samuel M. Pennell,S. L. Ramesh,Jeffrey Lopez,Ralph Spolenak,David C. Dunand
标识
DOI:10.1002/adem.202402635
摘要
Lamellar SnO 2 /Cu foams are created by directional freeze casting of SnO 2 /CuO slurries followed by liquid phase sintering and subsequent hydrogen reduction to achieve a two‐phase, interpenetrating SnO 2 ‐30 vol% Cu lamellar structure. The resulting SnO 2 /Cu foams exhibit both lamellar channels (millimeters in length) from the freeze‐casting step and submicron porosity within the Cu phase from the reduction step. This hierarchical microstructure provides increased electronic conductivity relative to unmodified SnO 2 . When applied as a negative electrode material for lithium‐ion batteries, the interaction between the mesoporous Cu phase and embedded SnO 2 enables the conversion reaction of the SnO 2 and Li to become reversible, improving the capacity of the electrode. However, the lamellar structure is ultimately unable to accommodate the expansion of the Sn during lithiation, resulting in a breakdown of the architecture during cycling.
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