Elucidation of the Charging Mechanisms and the Coupled Structural–Mechanical Behavior of Ti3C2Tx (MXenes) Electrodes by In Situ Techniques

Review (2023)
Author(s)

Gil Bergman (Bar-Ilan University)

Elad Ballas (Bar-Ilan University)

Qiang Gao (Oak Ridge National Laboratory)

Amey Nimkar (Bar-Ilan University)

Bar Gavriel (Bar-Ilan University)

Mikhael D. Levi (Bar-Ilan University)

Daniel Sharon (The Hebrew University of Jerusalem)

Fyodor Malchik (al-Farabi Kazakh National University, Almaty)

Xuehang Wang (TU Delft - Applied Sciences)

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Research Group
RST/Storage of Electrochemical Energy
DOI related publication
https://doi.org/10.1002/aenm.202203154 Final published version
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Publication Year
2023
Language
English
Research Group
RST/Storage of Electrochemical Energy
Issue number
8
Volume number
13
Article number
2203154
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Abstract

The discovery of the Ti3C2Tx compounds (MXenes) a decade ago opened new research directions and valuable opportunities for high-rate energy storage applications. The unique ability of the MXenes to host various mono- and multivalent cations and their high stability in different electrolyte environments including aqueous, organic, and ionic liquid solutions, promoted the rapid development of advanced MXene-based electrodes for a large variety of applications. Unlike the vast majority of typical intercalation compounds, the electrochemical performance of MXene electrodes is strongly influenced by the presence of co-inserted solvent molecules, which cannot be detected by conventional current/potential electrochemical measurements. Furthermore, the electrochemical insertion of ions into MXene interspaces results in strong coupling with the intercalation-induced structural, dimensional, and viscoelastic changes in the polarized MXene electrodes. To shed light on the charging mechanisms of MXene systems and their associated phenomena, the use of a large variety of real-time monitoring techniques has been proposed in recent years. This review summarizes the most essential findings related to the charging mechanism of Ti3C2Tx electrodes and their potential induced structural and mechanical phenomena obtained by in situ investigations.