A nanocrystalline Cu-doped tin oxide (5 nm) coating was obtained by electrodeposition in a nitrate solution with Cu as the substrate. The effects of the cutoff voltage range and heat treatment on the electrochemical behaviors of an electrodeposited SnO2 coating were examined. In a long-term test, both the decomposition of Li2O during the charging stage in the high-voltage range and the consumption of the electrolyte in the low-voltage range (0-0.3 V vs. Li/Li(superscript +)) damaged the electrochemical behavior of the Cu-doped tin oxide. The grain refinement during the discharging stage, caused by the transformation from Cu-doped SnO2 to metallic Sn and Cu, kept the grain size of the metallic particles at around 3 nm. This refinement avoided the capacity fading resulting from the grain growth of tin particles. Moreover, the heat treatment at 400℃ enhanced the cyclability, due to the elimination of an OH bond and adsorbed H2O molecules, where less Li2O formed during the first discharging stage reduced the electric resistivity compared with the as-deposited coating. In the case of 1.5V-0.3V, both a high capacity and good cycling were obtained due to the capacity contribution from the reaction of Li2O and good adhesion between the active particles and the Li2O matrix.