Nanostructured materials are much more effective than bulk materials when used as electrodes in lithium-ion batteries. This is because their smaller size allows lithium ions to move more quickly and easily, improving charge and discharge rates. They also handle the stress caused by lithium entering and leaving the material better. When the particle size is reduced to just a few nanometers, the way lithium reacts with the material can change significantly. For example, FeNbO4 with an -PbO2 structure behaves very differently ...
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Nanostructured materials are much more effective than bulk materials when used as electrodes in lithium-ion batteries. This is because their smaller size allows lithium ions to move more quickly and easily, improving charge and discharge rates. They also handle the stress caused by lithium entering and leaving the material better. When the particle size is reduced to just a few nanometers, the way lithium reacts with the material can change significantly. For example, FeNbO4 with an -PbO2 structure behaves very differently depending on its particle size. In a study, FeNbO4 was made in both nanometer and micrometer sizes using sol-gel (SG) and solid-state reaction (SSR) methods. Between the two crystal structures studied- -PbO2 and wolframite-the -PbO2 form showed better capacity retention.
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Add this copy of Exploring Lithium Intercalation in Dual-Phase FeNbO to cart. £42.09, new condition, Sold by Ingram Customer Returns Center rated 5.0 out of 5 stars, ships from NV, USA, published 2025 by LAP Lambert Academic Publishing.
Add this copy of Exploring Lithium Intercalation in Dual-Phase Fenbo? to cart. £47.64, new condition, Sold by Just one more Chapter rated 4.0 out of 5 stars, ships from Miramar, FL, UNITED STATES, published 2025 by LAP Lambert Academic Publishin.
