Progress of 2D MXene as an Electrode Architecture for Advanced Supercapacitors: A Comprehensive Review

Abstract: Supercapacitors, designed to store more energy and be proficient in accumulating more energy than conventional batteries with numerous charge–discharge cycles, have been developed in response to the growing demand for energy. Transition metal carbides/nitrides called MXenes have been the focus of researchers’ cutting-edge research in energy storage. The 2D-layered MXenes are a hopeful contender for the electrode material due to their unique properties, such as high conductivity, hydrophilicity, tunable surface… Show more

“…The morphology of MXene also has a great impact on its conductivity; single-layer and large-sized flakes have better interaction than multi-layered and small-sized flakes, usually improving conductivity [14,50,51]. In addition, compared with other 2D materials such as metal sulfides/hydroxides or graphene, MXene has plenty of chemical functional groups, for example, hydroxyl and fluorine atoms, and by changing these functional groups, the electronic structure and charge transfer properties of MXene can be controlled, affecting its conductivity performance [52]. Overall, the improvement of MXene conductivity is mainly due to its unique structure, containing transition metal elements and abundant chemical functional groups, which together make MXene an excellent conductive material with a multitude of potential applications.…”

“…Typically, through the selective removal of atomic layers, MXenes can be synthesized (for example, Al, Si, Ga, or Sn) from the MAX phase using different methods. When the metal-metallic M-A bonds in MAX materials are less powerful than the M-X covalent bonds, selective etching of the A layer atoms from MAX can be achieved, and it will not break the M-X bonds [18,33,52,59]. Currently, MXenes are produced by wet-chemical etching using HF or HF-containing or HF-generating etchants, resulting in the presence of -F surface terminations [45,[72][73][74].…”

Structure, Properties, and Preparation of MXene and the Application of Its Composites in Supercapacitors

“…The morphology of MXene also has a great impact on its conductivity; single-layer and large-sized flakes have better interaction than multi-layered and small-sized flakes, usually improving conductivity [14,50,51]. In addition, compared with other 2D materials such as metal sulfides/hydroxides or graphene, MXene has plenty of chemical functional groups, for example, hydroxyl and fluorine atoms, and by changing these functional groups, the electronic structure and charge transfer properties of MXene can be controlled, affecting its conductivity performance [52]. Overall, the improvement of MXene conductivity is mainly due to its unique structure, containing transition metal elements and abundant chemical functional groups, which together make MXene an excellent conductive material with a multitude of potential applications.…”

“…Typically, through the selective removal of atomic layers, MXenes can be synthesized (for example, Al, Si, Ga, or Sn) from the MAX phase using different methods. When the metal-metallic M-A bonds in MAX materials are less powerful than the M-X covalent bonds, selective etching of the A layer atoms from MAX can be achieved, and it will not break the M-X bonds [18,33,52,59]. Currently, MXenes are produced by wet-chemical etching using HF or HF-containing or HF-generating etchants, resulting in the presence of -F surface terminations [45,[72][73][74].…”

Structure, Properties, and Preparation of MXene and the Application of Its Composites in Supercapacitors

2D MXene incorporated nickel hydroxide composite for supercapacitor application

2D (Ti3C2Tx) MXene: A comprehensive review of advancements in synthesis protocols, applications in supercapacitors, sustainability targets and future prospects