straightforward electrochemical way. By simply tuning the soft templates and applying a suitable current density, a specific and unique microstructure is obtained. The diameter of the Ni(OH)(2) nano-Vhere is greatly influenced by the current density, the sample obtained at 1 mA"cm(-2) is about 200 nm while the size of that assembled at 6 mA center dot cm(-2) is less than 20 nm. However, the Ni(OH)(2) film prepared at the current density of 2 mA center dot cm(-2) showed the best electrochemical performance for the highly porous surface morphology which contributed to the uniform morphology obtained at this current density. The maximum specific capacitance can be achieved as high as 1460F center dot g(-1) in 2 M NaOH at the scan rate of 2mV center dot s(-1). Such impressive electrochemical properties can be ascribed to the highly porous microstructures and disorder of the amorphous phase which was considered for the better accommodation of repeated volume changes associated with doping-undoping process. The high specific capacitance and remarkable rate capability of amorphous transition metal oxides nanostructures show broad prospect for potential applications in energy conversion and storage devices. (C) 2015 Elsevier Ltd. All rights reserved.