Diamond-shaped Fe2O3@C18H34O2 core-shell nanostructures as anodes for lithium ion batteries with high over capacity

The over capacity of lithium ion batteries with metal-oxides anode materials is usually regarded as originating from the low-voltage decomposition of the electrolyte and subsequent formation of a gellike polymer layer deposited on the metal-oxides surfaces. In this work, we report a high over capacity value of 1800 mA h g(-1) after 350(th) charge-discharge cycles for Fe2O3-made lithium ion batteries. It is found that the capacitive nature of the designed Fe2O3@ C18H34O2 nanostructure not only contributes to the large observed excess in capacity, but also results in unique rate capabilities. Thus, a capacitive model is proposed to outline a plausible mechanism to explain these electrochemical findings, and it is anticipated that this paper will shed some new light on future design of the next generation of lithium ion batteries.