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1. Evolution of Surface Chemistry in Two‐Dimensional MXenes: From Mixed to Tunable Uniform Terminations

   https://doi.org/10.1002/anie.202409480  

   Jiang, Mengni; Wang, Di; Kim, Young‐Hwan; Duan, Chunying; Talapin, Dmitri_V; Zhou, Chenkun (August 2024, Angewandte Chemie International Edition)

   Abstract Surface chemistry of MXenes is of great interest as the terminations can define the intrinsic properties of this family of materials. The diverse and tunable terminations also distinguish MXenes from many other 2D materials. Conventional fluoride‐containing reagents etching approaches resulted in MXenes with mixed fluoro‐, oxo‐, and hydroxyl surface groups. The relatively strong chemical bonding of MXenes’ surface metal atoms with oxygen and fluorine makes post‐synthetic covalent surface modifications of such MXenes unfavorable. In this minireview, we focus on the recent advances in MXenes with uniform surface terminations. Unconventional methods, including Lewis acidic molten salt etching (LAMS) and bottom‐up direct synthesis, have been proven successful in producing halide‐terminated MXenes. These synthetic strategies have opened new possibilities for MXenes because weaker surface chemical bonds in halide‐terminated MXenes facilitate post‐synthetic covalent surface modifications. Both computational and experimental results on surface termination‐dependent properties are summarized and discussed. Finally, we offer our perspective on the opportunities and challenges in this exciting research field. 

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2. Covalent surface modifications and superconductivity of two-dimensional metal carbide MXenes

   https://doi.org/10.1126/science.aba8311  

   Kamysbayev, Vladislav; Filatov, Alexander S.; Hu, Huicheng; Rui, Xue; Lagunas, Francisco; Wang, Di; Klie, Robert F.; Talapin, Dmitri V. (July 2020, Science)

   Versatile chemical transformations of surface functional groups in two-dimensional transition-metal carbides (MXenes) open up a previously unexplored design space for this broad class of functional materials. We introduce a general strategy to install and remove surface groups by performing substitution and elimination reactions in molten inorganic salts. Successful synthesis of MXenes with oxygen, imido, sulfur, chlorine, selenium, bromine, and tellurium surface terminations, as well as bare MXenes (no surface termination), was demonstrated. These MXenes show distinctive structural and electronic properties. For example, the surface groups control interatomic distances in the MXene lattice, and Ti_n+1C_n(n= 1, 2) MXenes terminated with telluride (Te²⁻) ligands show a giant (>18%) in-plane lattice expansion compared with the unstrained titanium carbide lattice. The surface groups also control superconductivity of niobium carbide MXenes. 

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3. Photoexcited charge carrier dynamics and electronic properties of two-dimensional MXene, Nb ₂ CT _x

   https://doi.org/10.1088/2053-1583/ad518d  

   Fitzgerald, Andrew M; Sutherland, Emily; El-Melegy, Tarek Ali; Hassig, Mary Qin; Martin, Julia L; Colin-Ulloa, Erika; Ngo, Ken; Grimm, Ronald L; Uzarski, Joshua R; Barsoum, Michel W; et al (June 2024, 2D Materials)

   Two-dimensional, 2D, niobium carbide MXene, Nb2CTx, has attracted attention due to its extraordinarily high photothermal conversion efficiency that has applications ranging from medicine, for tumor ablation, to solar energy conversion. Here, we characterize its electronic properties and investigate the ultrafast dynamics of its photoexcitations with a goal of shedding light onto the origins of its unique properties. Through density functional theory, DFT, calculations, we find that Nb2CTx is metallic, with a small but finite DOS at the Fermi level for all experimentally relevant terminations that can be achieved using HF or molten salt etching of the parent MAX phase, including –OH, –O, –F, –Cl, –Br, –I. In agreement with this prediction, THz spectroscopy reveals an intrinsic long-range conductivity of ∼60 Ω−1 cm−1, with significant charge carrier localization and a charge carrier density (∼1020 cm−3) comparable to Mo-based MXenes. Excitation with 800 nm pulses results in a rapid enhancement in photoconductivity, which decays to less than 25% of its peak value within several picoseconds, underlying efficient photothermal conversion. At the same time, a small fraction of photoinjected excess carriers persists for hundreds of picoseconds and can potentially be utilized in photocatalysis or other energy conversion applications. 

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4. Combining X‐Ray Photoelectron and Absorption Spectroscopies for Determining Surface Chemistry and Composition of Ti ₃ C ₂ T _x MXene

   https://doi.org/10.1002/admi.202500391  

   Dessoliers, Zoé; Chemin, Arsène; Valurouthu, Geetha; Lord, Robert; Bilyk, Thomas; Gogotsi, Yury; Mauchamp, Vincent; Petit, Tristan (June 2025, Advanced Materials Interfaces)

   Abstract Surface chemistry and core composition of 2D MXenes play a major role in their interfacial properties, but the determination and quantification of their bonding environments remain challenging. X‐ray Photoelectron Spectroscopy (XPS) is a method of choice that is broadly utilized but is often hindered by large uncertainties and systematic bias due to adsorbed species such as adventitious carbon or etching residues. In this work, energy‐dependent XPS and depth profile modeling of the Ti₃C₂T_xMXene surface are employed to differentiate the contributions from the MXene and the adsorbed species, thereby increasing the accuracy of quantification. In comparison, uncorrected lab‐based XPS suffers from a systematic overestimation of Ti vacancies by 7% and an underestimation of terminal atoms, particularly F, by as much as 15%. Interestingly, it is found that a simple inelastic mean free path correction is sufficient to address the issue and reveals extremely low defects in Ti₃C₂T_xMXene synthesized using the HF/HCl etching route. Soft X‐ray Absorption Spectroscopy (XAS), supported by Density Functional Theory (DFT) calculations, also demonstrates a high chemical sensitivity of the surface terminations. This work provides novel insights into XPS quantification and the use of XAS for probing the carbide core and surface chemistry of Ti₃C₂T_xMXenes. 

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5. Self-etching Ti3C2Tx-SiOC ceramics: effects of MXene surface terminations on high-temperature ceramic nanocomposites

   https://doi.org/10.1007/s42114-025-01329-7  

   Rau, Advaith V; Lu, Kathy (June 2025, Advanced Composites and Hybrid Materials)

   Abstract Ti₃C₂T_x(MXenes) are novel 2D nanomaterials with exceptional electrical conductivity. Their surfaces are covered with functional groups that may significantly affect material properties such as hydrophobicity, electrical conductivity, and oxidation resistance. The role of these terminations in high-temperature ceramic systems with regard to phase and microstructural evolution has not been investigated. In this study, Ti₃C₂T_x-SiOC 2D nanocomposites were fabricated with -F and -OH terminated MXene to evaluate the role of surface terminations in silane coupling and phase formation during the polymer-to-ceramic transformation. X-ray diffraction (XRD), scanning electron microscopy (SEM), thermogravimetric analysis (TGA), and X-ray photoelectron spectroscopy (XPS) identified self-etching mechanisms caused by F-terminated Ti₃C₂T_xand revealed that the F surface terminations were retained in the MXene structure until evolution at ~ 550 °C. Evolved F reacted with Si–H bonds in the transforming ceramic matrix, causing additional mass loss and volumetric deformation. LiOH alkalization was shown to suppress the self-etching phenomenon through the substitution of F groups with OH on the nanosheet surface. Furthermore, F terminations were determined to only engage in hydrogen bonding with silane molecules as opposed to covalent linkages with OH terminations, which accelerated silane removal and Ti₃C₂T_xdegradation. The study provides a fundamental understanding of the nature and behavior of MXene surface terminations in the context of high-temperature ceramic nanocomposite fabrication. 

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