2022
DOI: 10.1002/smll.202201740
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Element‐Doped Mxenes: Mechanism, Synthesis, and Applications

Abstract: Heteroatom doping can endow MXenes with various new or improved electromagnetic, physicochemical, optical, and structural properties. This greatly extends the arsenal of MXenes materials and their potential for a spectrum of applications. This article comprehensively and critically discusses the syntheses, properties, and emerging applications of the growing family of heteroatom‐doped MXenes materials. First, the doping strategies, synthesis methods, and theoretical simulations of high‐performance MXenes mater… Show more

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Cited by 62 publications
(35 citation statements)
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“…The following conclusions can be obtained by analyzing Figure a–c: (1) TS (24) -P (50) -V 2 C delivers unexceptionable Gibbs free energy (GH*), and the absolute value of GH* is much lower than that of V 2 C-MXene, which ensures a faster H adsorption/desorption reaction process. (2) With the progress of the experimental steps, the results demonstrate that the GH* value of TS (24) -P (50) -V 2 C gradually approaches 0, which indicates that the theoretical catalytic activity of the electrocatalyst gradually increases with the progress of the experimental steps. , In addition to the DFT calculation of GH*, the water dissociation barrier of the catalyst can further prove the reason for the enhanced electrocatalytic activity at atomic level. As expected, the water dissociation barrier of V 2 C-MXene is higher than that of TS (24) -P (50) -V 2 C (Figure c).…”
Section: Resultsmentioning
confidence: 83%
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“…The following conclusions can be obtained by analyzing Figure a–c: (1) TS (24) -P (50) -V 2 C delivers unexceptionable Gibbs free energy (GH*), and the absolute value of GH* is much lower than that of V 2 C-MXene, which ensures a faster H adsorption/desorption reaction process. (2) With the progress of the experimental steps, the results demonstrate that the GH* value of TS (24) -P (50) -V 2 C gradually approaches 0, which indicates that the theoretical catalytic activity of the electrocatalyst gradually increases with the progress of the experimental steps. , In addition to the DFT calculation of GH*, the water dissociation barrier of the catalyst can further prove the reason for the enhanced electrocatalytic activity at atomic level. As expected, the water dissociation barrier of V 2 C-MXene is higher than that of TS (24) -P (50) -V 2 C (Figure c).…”
Section: Resultsmentioning
confidence: 83%
“…( 2) With the progress of the experimental steps, the results demonstrate that the GH* value of TS (24) -P (50) -V 2 C gradually approaches 0, which indicates that the theoretical catalytic activity of the electrocatalyst gradually increases with the progress of the experimental steps. 79,80 In addition to the DFT calculation of GH*, the water dissociation barrier of the catalyst can further prove the reason for the enhanced electrocatalytic activity at atomic level. As expected, the water dissociation barrier of V 2 C-MXene is higher than that of TS (24) -P (50) -V 2 C (Figure 7c).…”
Section: Acs Applied Materials and Interfacesmentioning
confidence: 99%
“…Compared with connecting high-cost photovoltaic and battery modules, SPRBs store solar energy by driving nonspontaneous reversible redox reactions in PEC cells through photoelectrode materials. [89,163,164] And delivering energy through reverse electrochemical reactions in the same device is much more cost-effective. [165,166] In order to obtain high conversion efficiency and high durability, photoanode with suitable energy level (energy level matching) needs to be considered when designing integrated photoelectrodes to meet the requirements (light harvesting efficiency and charge separation efficiency) of different devices.…”
Section: Photoelectrode Materialsmentioning
confidence: 99%
“…MXene thin films have been widely explored in lab-based applications, but still, an improvement is required for industrial scale. Further, doping of MXene with other elements could enhance their applicability in energy storage, sensing, and biomedical field [ 174 ]. Lastly, advanced electron microscopic studies of thin films of MXene materials could open a new door to surface functionalization and modification of such a novel material [ 175 ].…”
Section: Applications Of Thin Films Of Mxenesmentioning
confidence: 99%