Principle of surface treatment for electrochemical energy storage

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This review addresses synthetic approaches to control MOF attributes for realizing material properties such as charge conductivity, stability, surface area, and flexibility.

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This review elucidates surface engineering as a multi-faceted tool for engineering materials for energy storage that intersects the quest for new materials and the

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One major feature of MXenes is their tailorable surface terminations (e.g., −F, −O, −OH). Numerous studies have indicated that the composition of the surface terminations can

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Subsequently, simulation results of first-principles calculations are summarized, illustrating the role of surface terminations in the energy storage process. Finally, strategies for

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Electrochemical energy storage covers all types of secondary batteries. Batteries convert the chemical energy contained in its active materials into electric energy by an electrochemical

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Moreover, the surface terminations of MXenes prepared by this method are facile to further chemically modify, thus creating more opportunities for electrochemical energy

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About Principle of surface treatment for electrochemical energy storage

Specifically, the basic principles, characteristics, and challenges of these surface chemical strategies for improving electrolyte-wettability of electrode materials are discussed in detail.

In the present article, the recent advancements in surface modifications of the energy storage electrode materials and their electrochemical performances are summarized.

By highlighting these aspects, this Account underscores the transformative potential of surface modification and engineering in battery technology, paving the way for future innovations in energy storage solutions.

Thus, the modification of surface coatings can significantly improve the surface properties of energy storage materials, such as enhancing the conductivity, stability and cycle life of electrode materials, and optimizing the interfacial compatibility between electrolytes and electrodes.

One major feature of MXenes is their tailorable surface terminations (e.g., −F, −O, −OH). Numerous studies have indicated that the composition of the surface terminations can significantly impact the electrochemical properties of MXenes.

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6 FAQs about [Principle of surface treatment for electrochemical energy storage]

Why is surface modification of energy storage electrode materials important?

Among these techniques, surface modification of the electrode materials is widely used because of ease of synthesis and cost effectiveness. In the present article, the recent advancements in surface modifications of the energy storage electrode materials and their electrochemical performances are summarized.

Can surface chemical modification improve electrolyte-wettability of electrode materials?

Undoubtedly, surface chemical modification is the most useful strategy to improve the electrolyte-wettability of electrode materials for high electrochemical energy storage performance through its strong ability of regulating the surface chemical property of electrode materials.

Can surface modification improve energy storage performance of cathode materials?

To overcome these challenges of the existing cathode materials, it has been reported that surface modification of the cathode materials is a cost-effective and reasonable technology to enhance their energy storage performances such as capacity retention, cyclability, and thermal stability .

What is electrochemical energy storage?

As a constituent part of the energy storage system, electrochemical energy storage is a kind of devices that use chemical reactions to directly convert electrical energy. The electrode material determines the energy density and electrochemical properties of the battery.

Does electrolyte-wettability improve electrochemical energy storage performance of electrode material?

Therefore, the design and construction of electrode material surfaces with improved electrolyte-wettability has been demonstrated to be important to optimize electrochemical energy storage performance of electrode material.

Can active electrode materials be used for surface modification of cathode materials?

When active electrode materials are used for surface modification of cathode materials, there may be some loss of cathode material that can be fulfilled by the coating of active electrode materials. In this manner, the electrochemical performances of cathode materials also enhance due to the modification [174, 175].