Molybdenum-based materials/carbon nanotubes nanocomposites prepared as thin and transparent films for aqueous K-ion batteries

Thin films of nanocomposites composed of different molybdenum-based materials and carbon nanotubes were prepared and their performance as anodes in aqueous potassium-ion batteries was verified. The films were obtained through an innovative methodology based on the liquid/liquid interfacial route in a single-step procedure, starting from carbon nanotubes dispersions in chloroform or toluene, and molybdenum disulfide (or a mixture of amorphous molybdenum oxide/sulfide) dispersed in acetonitrile/water. The samples were characterized using different spectroscopic, microscopic, and electrochemical techniques, and it was observed a strong correlation between morphology and electrochemical performance. Materials obtained from chloroform dispersion of carbon nanotubes present more effective and intimate interaction between the components, which improves the electrochemical response. All the nanocomposites showed a pseudo-capacitive behavior in an aqueous solution of KC1, with a particularly good specific capacity, allowing their application as anodes in K-ion batteries fully operating in water. The best sample showed a specific capacity of 517 mAh g(-1) at 7 A g(-1) with a recovery degree close to 100%. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

Thin films of nanocomposites composed of different molybdenum-based materials and carbon nanotubes were prepared and tested as anodes in aqueous potassium-ion batteries. The materials obtained from carbon nanotubes dispersions in chloroform showed more effective interaction and improved electrochemical response. These nanocomposites exhibited pseudo-capacitive behavior with good specific capacity in an aqueous solution of KC1, making them suitable for use as anodes in K-ion batteries operating fully in water. The best sample showed a specific capacity of 517 mAh g(-1) at 7 A g(-1) with a recovery degree close to 100%.