Abstract
Highlighted by the safe operation and stable performances, titanium oxides (TiO(2)) are deemed as promising candidates for next generation lithium-ion batteries (LIBs). However, the pervasively low capacity is casting shadow on desirable electrochemical behaviors and obscuring their practical applications. In this work, we reported a unique template-assisted and two-step atomic layer deposition (ALD) method to achieve TiO(2)@Fe(2)O(3) core-shell nanotube arrays with hollow interior and double-wall coating. The as-prepared architecture combines both merits of the high specific capacity of Fe(2)O(3) and structural stability of TiO(2) backbone. Owing to the nanotubular structural advantages integrating facile strain relaxation as well as rapid ion and electron transport, the TiO(2)@Fe(2)O(3) nanotube arrays with a high mass loading of Fe(2)O(3) attained desirable capacity of ~520 mA h g(-1), exhibiting both good rate capability under uprated current density of 10 A g(-1) and especially enhanced cycle stability (~450 mA h g(-1) after 600 cycles), outclassing most reported TiO(2)@metal oxide composites. The results not only provide a new avenue for hybrid core-shell nanotube formation, but also offer an insight for rational design of advanced electrode materials for LIBs.