Ti3C2Tx Based Batteries and Super Capacitors

Authors

  • Fareeha Ghous

Keywords:

2D Material, MXene, titanium carbide, batteries, super capacitor

Abstract

A rise in energy necessities of the modern era entails the most actual, cost-effective, and long-lasting supplies for electrical energy sources. Because of the exceptional chemical and physical properties of 2D materials and their broad range of applications in energy storage devices, photo-catalysis, electronics, bio-sensors, gas sensors, water purification, and other fields, 2D MXene-based
nanomaterials have attracted a lot of attention. However, MXenes and their derivatives have plentiful intrinsic restrictions in terms of energy storage applications. The nano-engineering of these 2D materials is being considered widely in order to improve their performance for real-world applications.
This review article discusses the recent research and progress on Titanium Carbide nanostructures, with an emphasis on their preparation methods, properties, and applications for energy storage devices such as batteries and super-capacitors. In recent years, Titanium Carbide (Ti3C2Tx) has emerged as a
promising 2D material for various applications due to its unique properties. The preparation methods of Ti3C2Tx nanostructures play a crucial role in determining their properties and performance in energy storage devices. Various techniques, such as chemical etching, intercalation, and exfoliation, have been employed to fabricate Ti3C2Tx nanostructures with different morphologies and properties. The properties of Ti3C2Tx nanostructures, including their high surface area, excellent electrical conductivity, and good mechanical strength, make them ideal candidates for energy storage applications. These properties allow for high energy and power density, fast charge-discharge rates, and long cycle life in batteries and super-capacitors. In addition to energy storage devices, Ti3C2Tx nanostructures have shown great potential in other applications such as sensors, catalysis, and electromagnetic interference shielding. The unique properties of Ti3C2Tx nanostructures make them versatile materials for various technological applications.

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Published

2024-03-02

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