Mxene Phase(Mxene相)研究综述
Mxene Phase Mxene相 - The results illustrate that the proposed method is very facile and useful to incorporate mid-to-late transition metals into the MXene phase to prepare MXene based HER electrocatalysts. [1] This study presents new findings related to the incorporation of MXene phases into ceramic. [2] We used a combination of real and reciprocal space characterization (x-ray diffraction, x-ray photoelectron spectroscopy, energy dispersive x-ray spectroscopy, and scanning transmission electron microscopy) to establish the structure, phase purity, and equimolar distribution of the four transition metals in high-entropy MAX and MXene phases. [3] We used a combination of real and reciprocal space characterization (X-ray diffraction, X-ray photoelectron spectroscopy, energy dispersive X-ray spectroscopy, and scanning transmission electron microscopy) to establish the structure, phase purity, and equimolar distribution of the four transition metals in high-entropy MAX and MXene phases. [4] This article presents new findings related to the problem of the introduction of MXene phases into the silicon carbide matrix. [5] Finally, the perspectives and potential directions regarding material design concepts for 2D carbon-based nanomaterials and MXene phases for metal-ion storage are proposed. [6] The structure of the MXene phase after the sintering process was also analyzed. [7] The saturation magnetization of MAX and MXene phases is 49. [8] To circumvent the thermodynamic instability of MXene phases derived from mid-to-late transition metals, we have developed a synthetic strategy that allows the incorporation of such transition metal sites into a host MXene matrix. [9]结果表明,所提出的方法非常容易且可用于将中晚期过渡金属掺入 MXene 相中以制备基于 MXene 的 HER 电催化剂。 [1] 本研究提出了与将 MXene 相结合到陶瓷中相关的新发现。 [2] 我们结合使用实数和倒数空间表征(X 射线衍射、X 射线光电子能谱、能量色散 X 射线能谱和扫描透射电子显微镜)来确定四个跃迁的结构、相纯度和等摩尔分布高熵 MAX 和 MXene 相中的金属。 [3] 我们结合使用实数和倒数空间表征(X 射线衍射、X 射线光电子能谱、能量色散 X 射线能谱和扫描透射电子显微镜)来确定四个跃迁的结构、相纯度和等摩尔分布高熵 MAX 和 MXene 相中的金属。 [4] 本文介绍了与将 MXene 相引入碳化硅基质的问题相关的新发现。 [5] 最后,提出了关于二维碳基纳米材料和用于金属离子存储的 MXene 相的材料设计概念的观点和潜在方向。 [6] 还分析了烧结过程后 MXene 相的结构。 [7] MAX 和 MXene 相的饱和磁化强度为 49。 [8] 为了规避源自中后期过渡金属的 MXene 相的热力学不稳定性,我们开发了一种合成策略,允许将此类过渡金属位点结合到主体 MXene 基质中。 [9]