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Two‐Dimensional Materials for High‐Energy Solid‐State Asymmetric Pseudocapacitors with High Mass Loadings

2019; Wiley; Volume: 13; Issue: 6 Linguagem: Inglês

10.1002/cssc.201902339

1864-564X

Nilesh R. Chodankar, Swati J. Patil, G. Seeta Rama Raju, Dong‐Weon Lee, Deepak P. Dubal, Yun Suk Huh, Young‐Kyu Han,

Advanced battery technologies research

Abstract A porous nanostructure and high mass loading are crucial for a pseudocapacitor to achieve a good electrochemical performance. Although pseudocapacitive materials, such as MnO 2 and MoS 2 , with record capacitances close to their theoretical values have been realized, the achieved capacitances are possible only when the electrode mass loading is less than 1 mg cm −2 . Increasing the mass loading affects the capacitance as electron conduction and ion diffusion become sluggish. Achieving fast ion and electron transport at high mass loadings through all active sites remains a challenge for high‐mass‐loading electrodes. In this study, 2D MnO 2 nanosheets supported on carbon fibers (MnO 2 @CF) as well as MoS 2 @CF with high mass loadings (6.6 and 7.2 mg cm −2 , respectively) were used in a high‐energy pseudocapacitor. These hierarchical 2D nanosheets yielded outstanding areal capacitances of 1187 and 495 mF cm −2 at high current densities with excellent cycling stabilities. A pliable pseudocapacitive solid‐state asymmetric supercapacitor was designed using MnO 2 @CF and MoS 2 @CF as the positive and negative electrodes, respectively, with a high mass loading of 14.2 mg cm −2 . The assembled solid‐state asymmetric cell had an energy density of 2.305 mWh cm −3 at a power density of 50 mW cm −3 and a capacitance retention of 92.25 % over 11 000 cycles and a very small diffusion resistance (1.72 Ω s −1/2 ). Thus, it is superior to most state‐of‐the‐art reported pseudocapacitors. The rationally designed nanostructured electrodes with high mass loading are likely to open up new opportunities for the development of a supercapacitor device capable of supplying higher energy and power.