This paper proposes a method for the creation of molds with hierarchical micro/nano structures to enable the imprinting of conductive polymer polyaniline (PANI) for use as an electrode. The mold used for micro/nano structures was produced artificially. Photolithography was used to define an array of circular structures on a silicon substrate, followed by dry etching to create an array of cylinders with a diameter and height of 5 μm. Then nano pattern was produced and performed by dry etching to create a hierarchical structure. PDMS was used to form a soft mold to transfer this hierarchical structure to a PANI film, apply in the supercapacitor. 　　Using field emission scanning electron microscope (FE-SEM) confirmed that the surface structure of the film identification. On a three-electrode electrochemical cell, experiments were performed to characterize the electrochemical properties of plane PANI and PANI with microstructure and hierarchical microstructure, respectively. Cyclic voltammetric (CV), galvanostatic charge–discharge, and electrochemical impedance spectroscopy (EIS) measurements were then conducted using 1M H2SO4 as an electrolytic solution. 　　Its specific capacity value was obtained by the electrochemical measurement. Experiment results demonstrate that its specific capacity was 530 F/g, which is higher approximately 96% compared with PANI plane film , . Our results show that increasing the surface area of PANI through the inclusion of hierarchical structures enhanced oxidation/reduction reactions, leading to a higher average specific capacitance.