Article ID Journal Published Year Pages File Type
187885 Electrochimica Acta 2012 11 Pages PDF
Abstract

To keep up with the appeal for energy-saving and environment protection, scientists have turned to nature for inspiration to develop relative green approaches for the fabrication of materials. With this in mind, we demonstrate herein a green and facile method for the synthesis of Mn3O4 hierarchical materials with nanoscaled to microscaled porous structures. Nanostructured Mn3O4 thin films are prepared by green and facile successive ionic layer adsorption and reaction (SILAR) method. These films are further assembled in order to fabricate big as well as lightweight and portable Mn3O4–Mn3O4 symmetric supercapacitor cells. Scaling up has been realized by assembling several electrodes in parallel to build a prismatic cell. Electrochemical performance of these cells is tested by cyclic voltammetry and galvanostatic charge discharge techniques in neutral 1 M Na2SO4 aqueous electrolyte. A laboratory cell achieved a maximum specific capacitance of 72 F g−1 with stable performance >10,000 cycles and a cell voltage of 1 V. Long-life cycling was achieved by removing dissolved oxygen from the electrolyte, which limits the corrosion of current collectors. The effects of temperature on supercapacitive properties of Mn3O4–Mn3O4 symmetric cells are investigated. Additionally, actual demonstration of the cells with toy fan is given to prove the commercialization of the device. These encouraging results show the interest of developing such devices, including non-toxic and greener components as compared to the current organic-based devices.

Graphical abstractFabrication set-up of supercapacitor constructed using two identical electrodes of Mn3O4 material with Na2SO4 electrolyte; digital photographs of Mn3O4 thin film deposited on flexible substrate, different designs of big as well as portable Mn3O4–Mn3O4 symmetric supercapacitive devices.Figure optionsDownload full-size imageDownload as PowerPoint slideHighlights► Big as well as portable Mn3O4–Mn3O4 symmetric devices. ► Greener components such as electrolyte and separator. ► Efficient and stable supercapacitor. ► Temperature effect. ► Actual demonstration of device.

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Physical Sciences and Engineering Chemical Engineering Chemical Engineering (General)
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