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We hydrothermally synthesized In-doped rutile TiO 2 particles in an anionic surfactant solution and investigated the influences of In doping and the particle morphology on the Na + storage properties. The solid solubility limit was found to be 0.8 atom % in In-doped TiO 2 . In the case where no surfactant was used, the best anode performance was obtained for 0.8 atom % In-doped TiO 2 electrode by the benefits of three doping effects: (i) expanded diffusion-path size, (ii) improved electronic conductivity, and (iii) reduced electron charge density in the path. Further enhancement in the performance was achieved for the In-doped TiO 2 with a reduced particle length by the synthesis in the surfactant solution. This electrode exhibited a better cycle stability and maintained a high discharge capacity of 240 mA h g -1 for 200 cycles. The reason is probably that Na + can be inserted in the inner part of TiO 2 particles because of its reduced particle length.

Indium-Doped Rutile Titanium Oxide with Reduced Particle Length and Its Sodium Storage Properties